User Manual User Manual

ManualsBrandsRockwell Automation ManualsEquipment592- E300 Overload Relay

E300 Electronic Overload Relay

Bul. 193/592

User Manual

Summary of content (424 pages)

PAGE 1
User Manual E300 Electronic Overload Relay Bul.
PAGE 2
Important User Information Read this document and the documents listed in the additional resources section about installation, configuration, and operation of this equipment before you install, configure, operate, or maintain this product. Users are required to familiarize themselves with installation and wiring instructions in addition to requirements of all applicable codes, laws, and standards.
PAGE 3
Table of Contents Chapter 1 Product Overview Overview . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Modular Design . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Communication Options . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Diagnostic Information . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Simplified Wiring . . . . . . . . . . . .
PAGE 4
Table of Contents Expansion Bus Peripherals Dimensions. . . . . . . . . . . . . . . . . . . . . . . . . . . . . Terminals. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Sensing Module . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Control Module . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Expansion Digital Module. . . . . . . . . . . . . . . . . . . .
PAGE 5
Table of Contents Input Pt03 Assignment (Parameter 199) . . . . . . . . . . . . . . . . . . . . . . . Input Pt04 Assignment (Parameter 200) . . . . . . . . . . . . . . . . . . . . . . . Input Pt05 Assignment (Parameter 201) . . . . . . . . . . . . . . . . . . . . . . . Output Pt00 Assignment (Parameter 202) . . . . . . . . . . . . . . . . . . . . . Output Pt01 Assignment (Parameter 203) . . . . . . . . . . . . . . . . . . . . . Output Pt02 Assignment (Parameter 204) . . . . . . . . . . . . . . . . . . . .
PAGE 6
Table of Contents Start Inhibit Protection . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Preventive Maintenance. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Hardware Fault. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Configuration Trip . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Option Match. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
PAGE 7
Table of Contents Firmware Revision Number . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Control Module ID . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Sensing Module ID . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Operator Station ID . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Expansion Digital Module ID . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
PAGE 8
Table of Contents L2 Reactive Power . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . L3 Reactive Power . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Total Reactive Power . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . L1 Apparent Power . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . L2 Apparent Power . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
PAGE 9
Table of Contents Trip Snapshot L1-L2 Voltage. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Trip Snapshot L2-L3 Voltage. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Trip Snapshot L3-L1 Voltage. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Trip Snapshot Total Real Power . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Trip Snapshot Total Reactive Power . . . . . . . . . . . . . . . . . . . . . . . . . . Trip Snapshot Total Apparent Power .
PAGE 10
Table of Contents Resetting a Trip . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 319 Trip/Warn LED Troubleshooting Procedures . . . . . . . . . . . . . . . . . . . . . 320 Appendix A Specifications Electrical Specifications . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Low Voltage Directive . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Environmental Specifications. . . . . . .
PAGE 11
Chapter 1 Product Overview Overview The E300™ Electronic Overload Relay is a microprocessor-based electronic overload relay designed to protect three-phase or single-phase AC electric induction motors rated from 0.5…65,000 A. Its modular design, communication options, diagnostic information, simplified wiring, and integration into Logix makes this the ideal overload for motor control applications in an automation system.
PAGE 12
Chapter 1 Product Overview Diagnostic Information The E300 Electronic Overload Relay provides a wide variety of diagnostic information to monitor motor performance, proactively alert users to possible motor issues, or identify the reason for an unplanned shut down.
PAGE 13
Product Overview Catalog Number Explanation Chapter 1 E300 Electronic Overload Relay modules have their own catalog number. The catalog numbers are explained below. Sensing Module 193 - ESM - VIG - 30A - C23 592 Bulletin Number Module Type Sensing Module Type Sensing Current Range 193 IEC Overload Relay 592 NEMA Overload Relay ESM Sensing Module VIG Current, Ground Fault Current,  Voltage, & Power IG Current & Ground Fault Current I Current 30A 60A 100A 200A 0.
PAGE 14
Chapter 1 Product Overview Digital Expansion Module 193 - EXP - DIO - 42 - 120 Bulletin Number Module Type 193 IEC Overload Relay EXP Expansion Module DIO Digital I/O I/O Type I/O Count Communication Type 42 4 Inputs / 2 Relay Outputs 120 110…120V AC, 50/60 Hz Inputs 240 220…240V AC, 50/60 Hz Inputs 24D 24V DC Inputs Analog Expansion Module 193 - EXP - AIO - 31 Bulletin Number Module Type 193 IEC Overload Relay EXP Expansion Module AIO Analog I/O I/O Type I/O Count 31 3 Universal Analog
PAGE 15
Product Overview Module Description Chapter 1 The E300 Electronic Overload Relay is comprised of three modules. All three modules are required to make a functional overload relay. • Sensing Module • Control Module • Communication Module Sensing Module Figure 1 - Sensing Module The sensing module electronically samples the current, voltage, power, and energy data consumed by the electric motor internal to the module.
PAGE 16
Chapter 1 Product Overview Control Module Figure 2 - Control Module The control module is the heart of the E300 Electronic Overload Relay and can attach to any sensing module. The control module performs all of the protection and motor control algorithms and contains the native I/O for the system.
PAGE 17
Product Overview Chapter 1 turn dials, and it provides diagnostic LEDs to provide system status at the panel. The E300 Electronic Overload Relay supports two network protocols: • EtherNet/IP • DeviceNet The E300 EtherNet/IP Communication Module has two RJ-45 connectors that function as a switch. Users can daisy chain multiple E300 Electronic Overload Relays with Ethernet cable, and the module supports a Device Level Ring (DLR).
PAGE 18
Chapter 1 Product Overview Optional Operator Station Figure 4 - Operator Stations Power LED Escape Power LED Trip / Warn LED Up Trip / Warn LED Select LO C REM AL OT E Start Forward / Speed 1 Start Reverse / Speed 2 ESC 0 RES ET Local / Remote LO C REM AL OT E Start Forward / Speed 1 Stop Reset Start Reverse / Speed 2 SEL ECT 0 Enter RES ET Local / Remote Down Stop Control Station Diagnostic Station Reset The E300 Electronic Overload Relay offers the user the capability to add one o
PAGE 19
Product Overview Chapter 1 Overload Relay Expansion Bus (four Digital Expansion Modules, four Analog Expansion Modules, and one Operator Station).
PAGE 20
Chapter 1 Product Overview Applications: 20 The E300 Electronic Overload Relay can be used with the following across the line starter applications: • Non-Reversing Starter • Reversing Starter • Wye (Star) / Delta Starter • Two-speed Motors • Low and Medium Voltage with 2 or 3 Potential Transformers • With or Without Phase Current Transformers • With or Without Zero-sequence Core Balanced Current Transformer Rockwell Automation Publication 193-UM015B-EN-P - June 2014
PAGE 21
Chapter 2 Installation and Wiring Introduction This chapter provides instructions for receiving, unpacking, inspecting, and storing the E300™ Electronic Overload Relay. Assembly, installation, and wiring instructions for common applications are also included in this chapter. Receiving It is the responsibility of the user to thoroughly inspect the equipment before accepting the shipment from the freight company. Check the item(s) received against the purchase order.
PAGE 22
Chapter 2 Installation and Wiring General Precautions If the E300 Electronic Overload Relay is being deployed in an environment with an ambient temperature greater than 30 °C (86 °F), please refer to the Environmental Specifications on page 325 for the appropriate temperature derating. In addition to the specific precautions listed throughout this manual, the following general statements must be observed.
PAGE 23
Installation and Wiring Chapter 2 Any E300 Control Module can connect to any E300 Sensing Module. The illustrations below show the steps required to make this connection.
PAGE 24
Chapter 2 Installation and Wiring Any E300 Communication Module can connect to any E300 Control Module. The illustrations below show the steps required to make this connection.
PAGE 25
Installation and Wiring Chapter 2 The E300 Electronic Overload Relay offers a range of Expansion Digital and Analog I/O modules that simply connect to the E300 Electronic Overload Relay’s Expansion Bus.
PAGE 26
Chapter 2 Installation and Wiring Expansion Bus Digital & Analog I/O Modules and Power Supply Installation Figure 10 - Expansion Bus Digital& Analog I/O Modules and Power Supply 1 Click 2 Expansion Bus Operator Station Installation Figure 11 - Expansion Bus Operator Station 22 mm 2 1.7 N.
PAGE 27
Installation and Wiring Chapter 2 peripherals will require an Expansion Bus Power Supply which connects as the first module on the Expansion Bus. Users will set the address dial of the Expansion Digital Module to a unique digital module address number (1-4). If the Expansion Digital Module is the last device on the Expansion Bus, set the address to the address value that enables in the internal terminating resistor (1T-4T). A power cycle is required when changes are made to the address dial.
PAGE 28
Chapter 2 Installation and Wiring Starter Assembly The following illustrations show how to assemble an E300 Electronic Overload Relay as a motor starter with an Allen-Bradley Bulletin 100-C contactor.
PAGE 29
Installation and Wiring Chapter 2 Approximate dimensions are shown in millimeters (inches). Dimensions are not intended to be used for manufacturing purposes. Starter Dimensions Figure 14 - E300 Sensing Module 193-ESM-___-__-C23 with 100-C09…-C23 Contactor 87 (3.40) 45 (1.76) 35 (1.37) n 5 (0.18) 190 (7.49) 60 (2.3 (ADD 5 mm (0.19 in.) FOR CONTACTOR COIL ON LINE SIDE) 67 (2.65) 37 (1.47) FROM CONTACTOR MTG. HOLE 152 (5.98) 122 (4.81) 122 (4.78) 29 (1.14) FROM CONTACTOR MTG.
PAGE 30
Chapter 2 Installation and Wiring Figure 16 - E300 Sensing Module 193-ESM-___-__-C55 with 100-C43…-C55 Contactor 107 (4.21) 54 (2.12) 45 (1.75) n 5 (0.18) 60 (2. 190 (7.49) (ADD 5 mm (0.19 in.) FOR CONTACTOR COIL ON LINE SIDE) 67 (2.65) 37 (1.48) FROM CONTACTOR MTG. HOLE 152 (5.98) 34 (1.34) FROM CONTACTOR MTG. HOLE 122 (4.82) 45 (1.76) Figure 17 - E300 Sensing Module 592-ESM-___-__-S2 with NEMA Contactor Size 0 and Size 1 90 (3.56) n 6 (0.22) 180 (7.06) 157 (6.17) 249 (9.78) 12 (0.46) 35 (1.
PAGE 31
Installation and Wiring Chapter 2 Figure 18 - E300 Sensing Module 592-ESM-___-__-S2 with NEMA Contactor Size 2 100 (3.94) n 6 (0.22) 184 (7.24) 219 (8.63) 276 (10.85) 12 (0.46) 125 (4.91) 40 (1.58) 80 (3.15) DIN Rail / Panel Mount Dimensions Approximate dimensions are shown in millimeters (inches). Dimensions are not intended to be used for manufacturing purposes. Figure 19 - E300 Sensing Module 193-ESM-___-30A-E3T and 193-ESM-___-60A-E3T 30 (1.18) 126 (4.94) 45 (1.764) 6 (0.24) 9 (0.33) 46 (1.
PAGE 32
Chapter 2 Installation and Wiring Expansion Bus Peripherals Dimensions Approximate dimensions are shown in millimeters. Dimensions are not intended to be used for manufacturing purposes. Figure 20 - E300 Digital Expansion Module 193-EXP-DIO-___ 22.5 (0.89) 98 (3.86) 87 (3.43) 2 x 4.5 (0.18) dia. 80.75 (3.18) 120 (4.73) Figure 21 - E300 Expansion Analog Module 193-EXP-AIO 22.5 (0.89) 98 (3.86) 87 (3.43) 2 x 4.5 (0.18) dia. 80.75 (3.18) 120 (4.
PAGE 33
Installation and Wiring Chapter 2 Figure 22 - E300 Expansion Power Supply 193-EXP-PS-___ 45 (1.77) 4x 4.5 (0.18) dia 98 87 (3.86) (3.43) 120 (4.73) 80.75 (3.18) 12 (0.47) Figure 23 - E300 Starter Control Station 193-EOS-SCS 100 (3.94) 18.5 (0.73) 13.5 (0.53) 22.5 (0.89) dia. 45 (1.77) Figure 24 - E300 Starter Diagnostic Station 193-EOS-SDS 100 (3.94) 18.5 (0.73) 22.5 (0.89) dia. 13.5 (0.53) 70 (2.
PAGE 34
Chapter 2 Installation and Wiring Sensing Module Terminals Table 1 - E300 Sensing Module Wire Size and Torque Specifications Cat. No. Wire Type 193-ESM-_ _ _-30A-_ _ _ 193-ESM-_ _ _-60A-_ _ _ 592-ESM-_ _ _-30A-_ _ _ 592-ESM-_ _ _-60A-_ _ _ 193-ESM-_ _ _-100A-_ _ _ 592-ESM-_ _ _-100A-_ _ _ Single #14…6 AWG 22 lb-in. #12…1 AWG 35 lb-in. Multiple #10…6 AWG 30 lb-in. #6…2 AWG 35 lb-in. Single 2.5…16 mm2 2.5 N•m 4…35 mm2 4 N•m Multiple 6…10 mm2 3.4 N•m 4…25 mm2 4 N•m Single 2.5…25 mm2 2.
PAGE 35
Installation and Wiring Chapter 2 Control Module Figure 25 - E300 Control Module Terminal Designations 193-EIO-63- _ _ _ A1 R13 R14 A1 193-EIOGP-42- _ _ _ A1 A2 I N2 IN3 IN4 R13 R14 193-EIO-43- _ _ _ R13 R14 A1 A2 S1 Power / PTC Terminals 3 IT 1 IT 2 193-EIOGP-22- _ _ _ IN3 R23 R24 2 IN S2 A1 IN2 2 IN IN5 R23 R24 A1 A1 A R13 R14 S1 A1 A2 IT1 IT2 S2 Communication Module Latch Expansion Bus Connector Relay / Ground Fault Terminals IN1 IN0 A2 R04 R03 A1 Input / O
PAGE 36
Chapter 2 Installation and Wiring Table 2 - E300 Control Module Wire Size and Torque Specifications Wire Type Conductor Torque Stranded/Solid [AWG] Single Multiple (stranded only) Single Flexible-Stranded with Ferrule Metric Multiple Single Coarse-Stranded/Solid Metric Cat. No. 193-EIO-_ _-_ _ _ 193-EIOGP-_ _-_ _ _ 24...12 AWG 24...16 AWG 5 lb-in 0.25…2.5 mm2 0.5...0.75 mm2 0.55 N•m 0.2...2.5 mm2 0.2...1.5 mm2 0.
PAGE 37
Installation and Wiring Chapter 2 Expansion Digital Module Figure 27 - E300 Expansion Digital Module Terminal Designations RS2 R04 R14 RC3 IN2 IN3 IN0 IN1 INC Table 3 - E300 Expansion Digital Module Wire Size and Torque Specifications Wire Type Stranded/Solid [AWG] Flexible-Stranded with Ferrule Metric Coarse-Stranded/Solid Metric Conductor Torque Cat. No. 193-EXP-DIO-42-_ _ _ Single 24...12 AWG Multiple (stranded only) 24...16 AWG 5 lb-in Single 0.25…2.5 mm2 Multiple 0.5...0.75 mm2 0.
PAGE 38
Chapter 2 Installation and Wiring Figure 28 - E300 Expansion Digital Module Wiring Diagram R04 R14 RC3 + Source - IN0 IN1 IN2 IN3 INC Expansion Analog Module Figure 29 - E300 Expansion Analog Module Terminal Designations OUT+OUT- IN2+ IN2- RS2 IN1+ IN1- RS1 IN0+ IN0- RS0 38 Rockwell Automation Publication 193-UM015B-EN-P - June 2014
PAGE 39
Installation and Wiring Chapter 2 Table 4 - E300 Expansion Analog Module Wire Size and Torque Specifications Wire Type Conductor Torque Single Multiple (stranded only) Single Stranded/Solid [AWG] Flexible-Stranded with Ferrule Metric Multiple Single Coarse-Stranded/Solid Metric Multiple Cat. No. 193-EXP-AIO-31 24...12 AWG 24...16 AWG 5 lb-in 0.25…2.5 mm2 0.5...0.75 mm2 0.55 N•m 0.2...2.5 mm2 0.2...1.5 mm2 0.
PAGE 40
Chapter 2 Installation and Wiring Expansion Power Supply Figure 31 - E300 Expansion Power Supply Terminal Designations A1 A2 Table 5 - E300 Expansion Power Supply Wire Size and Torque Specifications Wire Type Conductor Torque Stranded/Solid [AWG] Flexible-Stranded with Ferrule Metric Coarse-Stranded/Solid Metric Single Multiple (stranded only) Single Multiple (stranded only) Single Multiple (stranded only) Figure 32 - E300 Expansion Power Supply Wiring Diagram + Source - A1 40 A2 Rockwell Aut
PAGE 41
Installation and Wiring Chapter 2 The following grounding recommendations are provided to ensure EMC requirements during installation. Grounding • The earth ground terminal of the E300 Electronic Overload Relay shall be connected to a solid earth ground via a low-impedance connection. • Wire the green shield wire of the Cat. No. 193-ECM-ETR into the earth ground terminal of the E300 control module.
PAGE 42
Chapter 2 Installation and Wiring Table 8 - High Fault Short Circuit Ratings per UL60947-4-1 and CSA 22.2 No. EN60947-4-1 with Bul. 100-C and 100-D IEC contactors protected by fuses Overload Relay using Sensing Module Cat. No. Contactor Cat. No. Max. Starter FLC[A] 100-C09 100-C12 100-C16 100-C23 100-C30 100-C37 100-C43 100-C55 9 12 16 23 30 37 43 55 193-ESM-___-30A-C23 193-ESM-___-30A-C55,  193-ESM-___-60A-C55 Max. Available Fault Current [A] Max.
PAGE 43
Installation and Wiring Chapter 2 Table 11 - Type 1 and Type II fuse coordination with Bul. 100-C and 100-D contactors per EN60947-4-1 Overload Relay using Sensing Module Cat. No. 193-ESM-___-30A-C23 193-ESM-___-30A-C55,  193-ESM-___-60A-C55 Contactor Cat. Max. Starter No. FLC[A] 100-C09 9 100-C12 12 100-C16 16 100-C23 23 100-C30 30 100-C37 37 100-C43 43 100-C55 55 Prospective Short-Circuit Current, Ir [A] Conditional ShortCircuit Current, Iq [A] 1000 100,000 3000 Max.
PAGE 44
Chapter 2 Installation and Wiring Figure 33 - E300 DOL and Single-Phase Full Voltage Connections Three-Phase Direct-On-Line S.C.P.D. L1 L3 L2 Single-Phase Full-Voltage S.C.P.D.
PAGE 45
Installation and Wiring Parameter Type Chapter 2 UINT Size (Bytes) 2 Scaling Factor 1 Units Amps Table 14 - CT Secondary (Parameter 264) CT Secondary (Parameter 264) Default Value 5 Minimum Value 1 Maximum Value 65535 Parameter Type UINT Size (Bytes) 2 Scaling Factor 1 Units Amps ATTENTION: Improper configuration of the CT Ratio parameters can result in the E300 Electronic Overload Relay reporting inaccurate motor operational data and possible motor damage.
PAGE 46
Chapter 2 Installation and Wiring Figure 34 - External Current Transformer Connection IEC NEMA L1 L2 L1 L3 L3 L2 K1 L1/1 L2/3 L3/5 L1/1 L2/3 L3/5 E300 Primary Current Transformers T1/2 T2/4 T3/6 E300 Primary Current Transformers T1/2 T2/4 T3/6 T1 M T2 T3 M The E300 Electronic Overload Relay voltage based sensing modules support a wide variety of power systems. Listed below are the power systems supported by the specific sensing module.
PAGE 47
Installation and Wiring Chapter 2 Table 16 - Voltage Mode (Parameter 352) Default Value 0 = Delta direct or with PTs 0 = Delta direct or with PTs 1 = Wye direct or with PTs Range 2 = Delta with Delta to Wye PTs 3 = Wye with Delta to Wye PTs 4 = Delta with Wye to Delta PTs 5 = Wye with Wye to Delta PTs Parameter Type USINT Size (Bytes) 1 Scaling Factor 1 Units Potential (Voltage) Transformer Ratio The E300 Electronic Overload Relay sensing module catalog number 193-ESMVIG-30A-CT can be used with
PAGE 48
Chapter 2 Installation and Wiring Control Circuits ATTENTION: Do not exceed the ratings of the E300 Electronic Overload Relay’s output and trip relay. If the coil current or voltage of the contactor exceeds the overload relay’s ratings, an interposing relay must be used. ATTENTION: When the power is applied to the E300 Electronic Overload Relay’s A1 and A2 terminals, the N.O. relay contact assigned as a Trip Relay will close after approximately 2 seconds if no trip condition exists.
PAGE 49
Installation and Wiring Chapter 2 Figure 36 - CENELEC Nomenclature L1 Relay 1 R13 R14 Relay 0 Configured as a Trip Relay 2 R03 R04 A1 K A2 N 2 Contact shown with supply voltage applied. Full-Voltage Reversing Starter (with Network Control) Figure 37 - NEMA Nomenclature Relay 0 Configured as a Trip Relay 1 Relay 1 REV R13 R14 A1 FOR A2 95 96 Relay 2 FOR R23 R24 A1 REV A2 1 Contact shown with supply voltage applied.
PAGE 50
Chapter 2 Installation and Wiring Figure 38 - CENELEC Nomenclature L1 Relay 0 Configured as a 2 Trip Relay R03 R04 Relay 1 R13 R23 Relay 2 R24 R14 K1 K2 A1 K1 A2 A1 K2 A2 2 Contact shown with supply voltage applied.
PAGE 51
Chapter 3 System Operation and Configuration Introduction This chapter provides instructions for operating and configuring an E300 Electronic Overload Relay system. Settings for Device Modes, Option Match, Security Policy, I/O Assignments, Expansion Bus Fault, Emergency Start, and an introduction to Operating Modes are included in this chapter.
PAGE 52
Chapter 3 System Operation and Configuration Operation Mode Operation Mode is a standby mode for the E300 Electronic Overload Relay in which the E300 is ready to protect an electric motor and no electrical current has been detected. Users can modify configuration parameters, upgrade firmware, and issue commands if the appropriate security policies are enabled.
PAGE 53
System Operation and Configuration Chapter 3 Table 20 - Run Mode Bit Function Detail — Device Status 0 (Parameter 20) Bit 15 14 13 12 11 10 9 8 7 6 5 4 3 2 1 0 Function X Trip Present X X X X X X X X X X X X X Warning Present Invalid Configuration Current Present GFCurrent Present Voltage Present Emergency Start Enabled DeviceLogix Enabled Feedback Timeout Enabled Operator Station Present Voltage Sensing Present Intern Ground Fault Sensing Present Extern Ground Fault Sensing Present PTC
PAGE 54
Chapter 3 System Operation and Configuration Table 21 - Invalid Configuration Cause (Parameter 39) Code 0 1 2 3 4 5 Description No Error Value over maximum value Value under minimum value Illegal value L3 Current detected (for single-phase applications) CopyCat error The Trip/Warn LED on the Communication Module and Operator Stations will be flashing a pattern of red, 3 long and 8 short blinks, and bits 0 and 2 in Device Status 0 (Parameter 20) are set to 1 when the device is in Invalid Configuration Mo
PAGE 55
System Operation and Configuration Chapter 3 Electronic Overload Relay system. Users can configure an option mismatch to cause a protection trip or provide a warning within the E300. Enable Option Match Protection Trip (Parameter 186) To enable the E300 Electronic Overload Relay’s Option Match feature to cause a protection trip in the event of an option mismatch, place a (1) in bit position 8 of Parameter 186 (Control Trip Enable).
PAGE 56
Chapter 3 System Operation and Configuration Enable Option Match Protection Warning (Parameter 192) To enable the E300 Electronic Overload Relay’s Option Match feature to cause a warning in the event of an option mismatch, place a (1) in bit position 8 of Parameter 192 (Control Warning Enable). Users can select the specific option match features to cause a warning in Parameter 233 (Option Match Action).
PAGE 57
System Operation and Configuration Chapter 3 Sensing Module Type (Parameter 222) The E300 Electronic Overload Relay offers 12 different sensing modules. Place the value of the expected sensing module into Parameter 222. A value of (0) disables the Option Match feature for the sensing module. Table 26 - Sensing Module Type (Parameter 222) Code 0 1 2 3 4 5 6 7 8 9 10 11 12 Description Ignore Voltage / Current 0.
PAGE 58
Chapter 3 System Operation and Configuration Operator Station Type (Parameter 224) The E300 Electronic Overload Relay offers two different types of operator stations. Place the value of the expected operator station into Parameter 224. A value of (0) disables the Option Match feature for the operator station.
PAGE 59
System Operation and Configuration Chapter 3 Digital I/O Expansion Module 2 Type (Parameter 226) The E300 Electronic Overload Relay supports up to four additional Digital I/O expansion modules. This parameter configures the Option Match feature for the Digital I/O expansion module at Digital Module Address 2. There are three different types of Digital I/O expansion modules. Place the value of the expected Digital I/O expansion module at Digital Module Address 2 into Parameter 226.
PAGE 60
Chapter 3 System Operation and Configuration Digital I/O Expansion Module 4 Type (Parameter 228) The E300 Electronic Overload Relay supports up to four additional Digital I/O expansion modules. This parameter configures the Option Match feature for the Digital I/O expansion module at Digital Module Address 4. There are three different types of Digital I/O expansion modules. Place the value of the expected Digital I/O expansion module at Digital Module Address 4 into Parameter 228.
PAGE 61
System Operation and Configuration Chapter 3 Analog I/O Expansion Module 2 Type (Parameter 230) The E300 Electronic Overload Relay supports up to four additional Analog I/O expansion modules. This parameter configures the Option Match feature for the Analog I/O expansion module at Analog Module Address 2. There are three different types of Analog I/O expansion modules. Place the value of the expected Analog I/O expansion module at Analog Module Address 2 into Parameter 230.
PAGE 62
Chapter 3 System Operation and Configuration Analog I/O Expansion Module 4 Type (Parameter 232) The E300 Electronic Overload Relay supports up to four additional Analog I/O expansion modules. This parameter configures the Option Match feature for the Analog I/O expansion module at Analog Module Address 4. There are three different types of Analog I/O expansion modules. Place the value of the expected Analog I/O expansion module at Analog Module Address 4 into Parameter 232.
PAGE 63
System Operation and Configuration Chapter 3 The E300 Electronic Overload Relay has a security policy that can be used to prevent users with malicious intent to potentially damage a motor or piece of equipment. By default, the user can only modify the security policy when the E300 Electronic Overload Relay is in Administration Mode (see page 51 to learn how to enable Administration Mode).
PAGE 64
Chapter 3 System Operation and Configuration Firmware Update Policy The Firmware Update Policy allows users to update the internal firmware of the communication module and control module via ControlFlash when the E300 Electronic Overload Relay is in Operation Mode. When this policy is disabled, firmware updates will return a communications error when the E300 Electronic Overload Relay is in Operation Mode or Run Mode.
PAGE 65
System Operation and Configuration Chapter 3 Input Pt01 Assignment (Parameter 197) Input Pt01 Assignment (Parameter 197) allows the user to assign this digital input for the following functions: Table 40 - Input Pt01 Assignment (Parameter 197) Value Assignment Description 0 Normal Function as a digital input 1 Trip Reset Reset the E300 when it is in a tripped state 2 Remote Trip Force a the E300 to go into a tripped state 3 Activate FLA2 Use the value in FLA2 Setting (Parameter 177) for the
PAGE 66
Chapter 3 System Operation and Configuration Input Pt03 Assignment (Parameter 199) Input Pt03 Assignment (Parameter 199) allows the user to assign this digital input for the following functions: Table 42 - Input Pt03 Assignment (Parameter 199) Value 0 Assignment Normal Description Function as a digital input 1 Trip Reset Reset the E300 when it is in a tripped state 2 Remote Trip Force a the E300 to go into a tripped state 3 Activate FLA2 Use the value in FLA2 Setting (Parameter 177) for the cur
PAGE 67
System Operation and Configuration Chapter 3 Input Pt05 Assignment (Parameter 201) Input Pt05 Assignment (Parameter 201) allows the user to assign this digital input for the following functions: Table 44 - Input Pt05 Assignment (Parameter 201) Value Assignment Description 0 Normal Function as a digital input 1 Trip Reset Reset the E300 when it is in a tripped state 2 Remote Trip Force a the E300 to go into a tripped state 3 Activate FLA2 Use the value in FLA2 Setting (Parameter 177) for the
PAGE 68
Chapter 3 System Operation and Configuration Output Pt00 Assignment (Parameter 202) Output Pt00 Assignment (Parameter 202) allows the user to assign this relay output for the following functions: Table 45 - Output Pt00 Assignment (Parameter 202) Value 0 1 2 3 4 Assignment Description Normal Function as a relay output Function as a normally closed contact until the E300 is in a tripped state in which the relay Trip Relay opens. The Trip Relay remains open until a trip reset is issued.
PAGE 69
System Operation and Configuration Chapter 3 Output Pt02 Assignment (Parameter 204) Output Pt02 Assignment (Parameter 204) allows the user to assign this relay output for the following functions: Table 47 - Output Pt02 Assignment (Parameter 204) Value 0 1 2 3 4 Assignment Description Normal Function as a relay output Function as a normally closed contact until the E300 is in a tripped state in which the relay Trip Relay opens. The Trip Relay remains open until a trip reset is issued.
PAGE 70
Chapter 3 System Operation and Configuration Expansion Bus Trip Expansion Bus Trip is enabled by setting Control Trip Enable (Parameter 186) bit 10 to 1. When communications is disrupted between the Control Module and digital and/or analog expansion I/O modules, the E300 Electronic Overload Relay will go into a tripped state in which the Trip/Warn LED on the Communication Module and Operator station will blink a red 3 long and 11 short blinking pattern.
PAGE 71
System Operation and Configuration Chapter 3 Expansion Bus Warning Expansion Bus Warning is enabled by setting Control Warning Enable (Parameter 192) bit 10 to 1. When communications is disrupted between the Control Module and digital and/or analog expansion I/O modules, the E300 Electronic Overload Relay will go into a warning state in which the Trip/Warn LED on the Communication Module and Operator station will blink a yellow 3 long and 11 short blinking pattern.
PAGE 72
Chapter 3 System Operation and Configuration Configure one of the Ptxx Input Assignments (Parameters 196…201) to Emergency Start and activate the corresponding digital input.
PAGE 73
System Operation and Configuration Introduction to Operating Modes Chapter 3 The E300 Electronic Overload Relay supports a number of Operating Modes, which consist of configuration rules and logic to control typical full voltage motor starters, including: • Overload • Non-Reversing Starter • Reversing Starter • Wye/Delta (Star/Delta) Starter • Two-Speed Starter • Monitor The default Operating Mode (Parameter 195) for the E300 Electronic Overload Relay is Overload (Network) in which the E300 Electronic Ov
PAGE 74
Chapter 3 74 System Operation and Configuration Rockwell Automation Publication 193-UM015B-EN-P - June 2014
PAGE 75
Chapter 4 Operating Modes Introduction The E300™ Electronic Overload Relay supports up to 54 Operating Modes which consist of configuration rules and logic to control typical full voltage motor starters including: • Overload • Non-Reversing Starter • Reversing Starter • Wye/Delta (Star/Delta) Starter • Two Speed Starter • Monitoring Device This chapter explains the configuration rules, logic, and control wiring required for the available Operating Modes (Parameter 195).
PAGE 76
Chapter 4 Operating Modes Figure 39 - Wiring Diagram Relay 0 Configured as a Trip Relay 1 Relay 1 R13 R14 A1 M A2 R03 R04 1 Contact shown with supply voltage applied. Timing Diagram Figure 40 - Timing Diagram Trip Relay Device Status0.Trip Present Trip Reset Monitor (Custom) The E300 Electronic Overload Relay’s Monitor (Custom) Operating Mode allows the user to use the E300 Electronic Overload Relay as a monitoring device.
PAGE 77
Chapter 5 Protective Trip and Warning Functions Introduction The purpose of this chapter is to provide detailed information regarding the protective trip and warning functions of the E300Electronic Overload Relay.
PAGE 78
Chapter 5 Protective Trip and Warning Functions Current Trip Enable (Parameter 183) and Current Warning Enable (Parameter 189) are used to enable the respective current based protective trip and warning functions.
PAGE 79
Protective Trip and Warning Functions Chapter 5 Current Trip Status (Parameter 4) and Current Warning Status (Parameter 10) are used to monitor the respective current based protective trip and warning functions.
PAGE 80
Chapter 5 Protective Trip and Warning Functions Overload Protection The E300 Electronic Overload Relay provides overload protection through true RMS current measurements of the individual phase currents of the connected motor. Based on the highest current measured, the programmed FLA Setting, and Trip Class, a thermal model that simulates the actual heating of the motor is calculated.
PAGE 81
Protective Trip and Warning Functions IMPORTANT Chapter 5 The Protection Fault State of Relay 0, Relay 1, Relay 2, Digital Module 1 Output Relays, Digital Module 2 Output Relays, Digital Module 3 Output Relays, and Digital Module 4 Output Relays are defined by the respective parameters: • Output PT00 Protection Fault Action (Parameter 304) • Output PT00 Protection Fault Value (Parameter 305) • Output PT01 Protection Fault Action (Parameter 310) • Output PT01 Protection Fault Value (Parameter 311) • Outpu
PAGE 82
Chapter 5 Protective Trip and Warning Functions Table 59 - FLA2 (Parameter 177) FLA2 (Parameter 177) Default Value Minimum Value Maximum Value Parameter Type Size (Bytes) Scaling Factor Units 0.50 (0.5…30 A Sensing Modules) 6.00 (6…60 A Sensing Modules) 10.00 (10…100 A Sensing Modules) 20.00 (20…200 A Sensing Modules) 0.50 65535.00 UDINT 4 100 Amps USA & Canada Guidelines • Motor Service Factor ≥ 1.15: For motors with a service factor rating of 1.
PAGE 83
Protective Trip and Warning Functions Chapter 5 Trip Curves The following figures illustrate the E300 Electronic Overload Relay’s timecurrent characteristics for trip classes 5, 10, 20, and 30.
PAGE 84
Chapter 5 Protective Trip and Warning Functions Automatic/Manual Reset Overload Reset Mode (Parameter 173) allows the user to select the reset mode for the E300 Electronic Overload Relay after an overload or thermistor (PTC) trip. If an overload trip occurs and automatic reset mode is selected, the E300 Electronic Overload Relay will automatically reset when the value stored in % Thermal Capacity Utilized (Parameter 1) falls below the value stored in Overload Reset Level (Parameter 174).
PAGE 85
Protective Trip and Warning Functions Chapter 5 Overload Reset Level (Parameter 174) is adjustable from 1 to 100% TCU. The following figures illustrate the typical overload reset time delay when Overload Reset Level is set to 75% TCU.
PAGE 86
Chapter 5 Protective Trip and Warning Functions • Bit 1 in Device Status 0 (Parameter 20) will set to 1 • Any relay outputs configured as Warning Alarm will close Overload Warning Level (Parameter 175) can be used as an alert for an impending overload trip and is adjustable from 0…100% TCU.
PAGE 87
Protective Trip and Warning Functions Chapter 5 Table 66 - Overload Time to Reset (Parameter 3) Overload Time to Reset (Parameter 3) Default Value 0 Minimum Value 0 Maximum Value 9999 Parameter Type UINT Size (Bytes) 2 Scaling Factor 1 Units Sec Non-Volatile Thermal Memory The E300 Electronic Overload Relay includes a non-volatile circuit to provide thermal memory. The time constant of the circuit corresponds to a Trip Class 20 setting.
PAGE 88
Chapter 5 Protective Trip and Warning Functions IMPORTANT The phase loss inhibit timer starts after the maximum phase of load current transitions from 0 A to 30% of the device’s minimum FLA Setting. The E300 Electronic Overload Relay does not begin monitoring for a phase loss condition until the Phase Loss Inhibit Time expires.
PAGE 89
Protective Trip and Warning Functions Chapter 5 Phase Loss Trip Delay Phase Loss Trip Delay (Parameter 240) allows the user to define the time period for which a phase loss condition must be present before a trip occurs. It is adjustable from 0.1…25.0 seconds. Table 68 - Phase Loss Trip Delay (Parameter 240) Phase Loss Trip Delay (Parameter 240) Default Value Minimum Value Maximum Value Parameter Type Size (Bytes) Scaling Factor Units 1.0 0.1 25.
PAGE 90
Chapter 5 Protective Trip and Warning Functions ATTENTION: The E300 Electronic Overload Relay is not a ground fault circuit interrupt or for personal protection as defined in Article 100 of the NEC. ATTENTION: The E300 Electronic Overload Relay is not intended to signal a disconnecting means to open the faulted current. A disconnecting device must be capable of interrupting the maximum available fault current of the system on which it is used.
PAGE 91
Protective Trip and Warning Functions Chapter 5 Table 71 - Overload Reset Level (Parameter 248) Overload Reset Level (Parameter 248) Default Value 0 = Disable Minimum Value 0 = Disable Maximum Value 1 = Enable Parameter Type BOOL Size (Bytes) 1 Scaling Factor 1 Units Ground Fault Filter An E300 Electronic Overload Relay has the capability to filter ground fault currents for High Resistance Grounded (HRG) systems from its current-based protection trip and warning functions which includes: • Th
PAGE 92
Chapter 5 Protective Trip and Warning Functions Table 73 - Ground Fault Inhibit Time (Parameter 242 Ground Fault Inhibit Time (Parameter 242) Default Value 0 Minimum Value 0 Maximum Value 250 Parameter Type USINT Size (Bytes) 1 Scaling Factor 1 Units Sec Table 74 - Device Status 0 (Parameter 20) Bit 15 14 13 12 11 10 9 8 7 6 5 4 3 2 1 0 Function X Trip Present X X X X X X X X X X X X X X Warning Present Invalid Configuration Current Present Ground Fault Current Present Volt
PAGE 93
Protective Trip and Warning Functions • • • • • Chapter 5 Bit 0 of Device Status 0 (Parameter 20) will set to 1 Any relay outputs configured as a Trip Relay will open Any relay outputs configured as a Control Relay will open Any relay outputs configured as a Trip Alarm will close Any relay outputs configured as a Normal Relay will be placed in their Protection Fault state (if so programmed) IMPORTANT The Protection Fault State of Relay 0, Relay 1, Relay 2, Digital Module 1 Output Relays, Digital Module
PAGE 94
Chapter 5 Protective Trip and Warning Functions Table 75 - Ground Fault Trip Delay (Parameter 243) Ground Fault Trip Delay (Parameter 243) Default Value 0.5 Minimum Value 0.0 Maximum Value 25.0 Parameter Type USINT Size (Bytes) 1 Scaling Factor 10 Units Sec Ground Fault Trip Level Ground Fault Trip Level (Parameter 244) allows the user to define the ground fault current in which the E300 Electronic Overload Relay will trip and is adjustable from: • 0.500…5.00 A (Internal) • 0.020…5.
PAGE 95
Protective Trip and Warning Functions Chapter 5 • Ground Fault Current is equal to or greater than the Ground Fault Warning Level for a time period greater than the Ground Fault Warning Delay.
PAGE 96
Chapter 5 Protective Trip and Warning Functions Stall Protection A motor stalls when its inrush current lasts for a longer than normal period of time during its starting sequence. As a result, the motor heats up very rapidly and reaches the temperature limit of its insulation. Rapid stall detection during the starting sequence can extend the motor’s life, as well as minimize potential damage and loss of production.
PAGE 97
Protective Trip and Warning Functions IMPORTANT Chapter 5 The Protection Fault State of Relay 0, Relay 1, Relay 2, Digital Module 1 Output Relays, Digital Module 2 Output Relays, Digital Module 3 Output Relays, and Digital Module 4 Output Relays are defined by the respective parameters: • Output PT00 Protection Fault Action (Parameter 304) • Output PT00 Protection Fault Value (Parameter 305) • Output PT01 Protection Fault Action (Parameter 310) • Output PT01 Protection Fault Value (Parameter 311) • Outpu
PAGE 98
Chapter 5 Protective Trip and Warning Functions Table 80 - Stall Trip Level (Parameter 250) Stall Trip Level (Parameter 250) Default Value 600 Minimum Value 100 Maximum Value 600 Parameter Type UINT Size (Bytes) 2 Scaling Factor 1 Units %FLA IMPORTANT Stall Protection is only enabled during the motor starting sequence.
PAGE 99
Protective Trip and Warning Functions Chapter 5 Jam Trip The E300 Electronic Overload Relay will trip with a jam indication if: • No trip currently exists • Jam Trip is enabled • Jam Inhibit Time has expired • The maximum phase current is greater than the Jam Trip Level for a time period greater than the Jam Trip Delay.
PAGE 100
Chapter 5 Protective Trip and Warning Functions Table 82 - Jam Trip Delay (Parameter 252) Default Value 5.0 Minimum Value 0.1 Maximum Value 25.0 Parameter Type USINT Size (Bytes) 1 Scaling Factor 10 Units Sec Jam Trip Level Jam Trip Level (Parameter 253) allows the installer to define the current at which the E300 Electronic Overload Relay will trip on a jam. It is user-adjustable from 50…600% of the FLA Setting (Parameter 171).
PAGE 101
Protective Trip and Warning Functions Chapter 5 Jam Warn Level Jam Warn Level (Parameter 254) allows the user to define the current at which the E300 Electronic Overload Relay will indicate a warning. It is user-adjustable from 50…600% for the FLA Setting (Parameter 171).
PAGE 102
Chapter 5 Protective Trip and Warning Functions Underload Trip The E300 Electronic Overload Relay will trip with an underload indication if: • No trip currently exists • Underload Trip is enabled • Current is present • Underload Inhibit Time has expired • Minimum phase current is less than the Underload Trip Level for a time period greater than the Underload Trip Delay.
PAGE 103
Protective Trip and Warning Functions Chapter 5 Table 86 - Underload Trip Delay (Parameter 256) Default Value 5.0 Minimum Value 0.1 Maximum Value 25.0 Parameter Type USINT Size (Bytes) 1 Scaling Factor 10 Units Sec Underload Trip Level Underload Trip Level (Parameter 257) allows the installer to define the current at which the E300 Electronic Overload Relay will trip on an underload. It is useradjustable from 10…100% of the FLA Setting (Parameter 171).
PAGE 104
Chapter 5 Protective Trip and Warning Functions • • • • TRIP/WARN LED will flash a yellow 6-short blink pattern Bit 5 in Current Warning Status (Parameter 10) will set to 1 Bit 1 in Device Status 0 (Parameter 20) will set to 1 Any relay outputs configured as a Warning Alarm will close Underload Warning Level Underload Warning Level (Parameter 258) allows the user to define the current at which the E300 Electronic Overload Relay will indicate a warning.
PAGE 105
Protective Trip and Warning Functions Chapter 5 Current Imbalance Inhibit Time Current Imbalance Inhibit Time (Parameter 259) allows the installer to inhibit a current imbalance trip and warning from occurring during the motor starting sequence. It is adjustable from 0…250 s.
PAGE 106
Chapter 5 Protective Trip and Warning Functions IMPORTANT The Protection Fault State of Relay 0, Relay 1, Relay 2, Digital Module 1 Output Relays, Digital Module 2 Output Relays, Digital Module 3 Output Relays, and Digital Module 4 Output Relays are defined by the respective parameters: • Output PT00 Protection Fault Action (Parameter 304) • Output PT00 Protection Fault Value (Parameter 305) • Output PT01 Protection Fault Action (Parameter 310) • Output PT01 Protection Fault Value (Parameter 311) • Outpu
PAGE 107
Protective Trip and Warning Functions Chapter 5 Table 91 - Current Imbalance Trip Level (Parameter 261) Default Value 35 Minimum Value 10 Maximum Value 100 Parameter Type USINT Size (Bytes) 1 Scaling Factor 1 Units % IMPORTANT The Current Imbalance Inhibit Timer starts after a phase of load current transitions from 0A to 30% of the device’s minimum FLA setting.
PAGE 108
Chapter 5 Protective Trip and Warning Functions Table 92 - Current Imbalance Warning Level (Parameter 262) Default Value 20 Minimum Value 10 Maximum Value 100 Parameter Type USINT Size (Bytes) 1 Scaling Factor 1 Units % IMPORTANT The Current Imbalance Warning function does not include a time delay feature. Once the Current Imbalance Inhibit Time has expired, the Current Imbalance Warning indication is instantaneous.
PAGE 109
Protective Trip and Warning Functions • • • • • • • • • • • • • Chapter 5 No trip currently exists L1 Under Current Trip is enabled Current is present Under Current Inhibit Timer has expired L1 Percent FLA (Parameter 47) is less than the L1 Under Current Trip Level for a time period greater than the L1 Under Current Trip Delay.
PAGE 110
Chapter 5 Protective Trip and Warning Functions Table 94 - L1 Under Current Trip Delay (Parameter 266) Default Value Minimum Value Maximum Value Parameter Type Size (Bytes) Scaling Factor Units 1.0 0.1 25.0 USINT 1 10 Sec L1 Under Current Trip Level L1 Under Current Trip Level (Parameter 267) allows the installer to define the current at which the E300 Electronic Overload Relay will trip on a L1 Under Current. It is user-adjustable from 10…100% of the FLA Setting (Parameter 171).
PAGE 111
Protective Trip and Warning Functions Chapter 5 When the L1 Under Current Warning conditions are satisfied, the: • TRIP/WARN LED will flash a yellow 8-short blink pattern • Bit 7 in Current Warning Status (Parameter 10) will set to 1 • Bit 1 in Device Status 0 (Parameter 20) will set to 1 • Any relay outputs configured as a Warning Alarm will close L1 Under Current Warning Level L1 Under Current Warning Level (Parameter 268) allows the user to define the current at which the E300 Electronic Overload Rela
PAGE 112
Chapter 5 Protective Trip and Warning Functions • Any relay outputs configured as a Normal Relay will be placed in their Protection Fault state (if so programmed) IMPORTANT The Protection Fault State of Relay 0, Relay 1, Relay 2, Digital Module 1 Output Relays, Digital Module 2 Output Relays, Digital Module 3 Output Relays, and Digital Module 4 Output Relays are defined by the respective parameters: • Output PT00 Protection Fault Action (Parameter 304) • Output PT00 Protection Fault Value (Parameter 305)
PAGE 113
Protective Trip and Warning Functions Chapter 5 Table 98 - L2 Under Current Trip Level Parameter 270) Default Value Minimum Value Maximum Value Parameter Type Size (Bytes) Scaling Factor Units 35 10 100 USINT 1 1 %FLA IMPORTANT The Under Current Inhibit Timer starts after the maximum phase of load current transitions from 0A to 30% of the device’s minimum FLA setting.
PAGE 114
Chapter 5 Protective Trip and Warning Functions Table 99 - L2 Under Current Warning Level (Parameter 271) Default Value Minimum Value Maximum Value Parameter Type Size (Bytes) Scaling Factor Units IMPORTANT 40 10 100 USINT 1 1 %FLA The L2 Under Current Warning function does not include a time delay feature. Once the Under Current Inhibit Timer has expired, the L2 Under Current Warning indication is instantaneous.
PAGE 115
Protective Trip and Warning Functions Chapter 5 IMPORTANT The Protection Fault State of Relay 0, Relay 1, Relay 2, Digital Module 1 Output Relays, Digital Module 2 Output Relays, Digital Module 3 Output Relays, and Digital Module 4 Output Relays are defined by the respective parameters: • Output PT00 Protection Fault Action (Parameter 304) • Output PT00 Protection Fault Value (Parameter 305) • Output PT01 Protection Fault Action (Parameter 310) • Output PT01 Protection Fault Value (Parameter 311) • Outpu
PAGE 116
Chapter 5 Protective Trip and Warning Functions Table 101 - L3 Under Current Trip Level (Parameter 273) Default Value Minimum Value Maximum Value Parameter Type Size (Bytes) Scaling Factor Units 35 10 100 USINT 1 1 %FLA IMPORTANT The Under Current Inhibit Timer starts after the maximum phase of load current transitions from 0A to 30% of the device’s minimum FLA setting.
PAGE 117
Protective Trip and Warning Functions Chapter 5 Table 102 - L3 Under Current Warning Level (Parameter 274) Default Value Minimum Value Maximum Value Parameter Type Size (Bytes) Scaling Factor Units IMPORTANT 40 10 100 USINT 1 1 %FLA The L3 Under Current Warning function does not include a time delay feature. Once the Under Current Inhibit Timer has expired, the L3 Under Current Warning indication is instantaneous.
PAGE 118
Chapter 5 Protective Trip and Warning Functions • Current is present • Over Current Inhibit Timer has expired • L1 Percent FLA (Parameter 47) is greater than the L1 Over Current Trip Level for a time period greater than the L1 Over Current Trip Delay.
PAGE 119
Protective Trip and Warning Functions Chapter 5 Table 104 - L1 Over Current Trip Delay (Parameter 276) Default Value 1.0 Minimum Value 0.1 Maximum Value 25.0 Parameter Type USINT Size (Bytes) 1 Scaling Factor 10 Units Sec L1 Over Current Trip Level L1 Over Current Trip Level (Parameter 277) allows the installer to define the current at which the E300 Electronic Overload Relay will trip on a L1 Over Current. It is user-adjustable from 10…100% of the FLA Setting (Parameter 171).
PAGE 120
Chapter 5 Protective Trip and Warning Functions • Any relay outputs configured as a Warning Alarm will close L1 Over Current Warning Level L1 Over Current Warning Level (Parameter 278) allows the user to define the current at which the E300 Electronic Overload Relay will indicate a L1 Over Current warning. It is user-adjustable from 10…100% for the FLA Setting (Parameter 171).
PAGE 121
Protective Trip and Warning Functions IMPORTANT Chapter 5 The Protection Fault State of Relay 0, Relay 1, Relay 2, Digital Module 1 Output Relays, Digital Module 2 Output Relays, Digital Module 3 Output Relays, and Digital Module 4 Output Relays are defined by the respective parameters: • Output PT00 Protection Fault Action (Parameter 304) • Output PT00 Protection Fault Value (Parameter 305) • Output PT01 Protection Fault Action (Parameter 310) • Output PT01 Protection Fault Value (Parameter 311) • Outpu
PAGE 122
Chapter 5 Protective Trip and Warning Functions Table 108 - L2 Over Current Trip Level (Parameter 280). Default Value Minimum Value Maximum Value Parameter Type Size (Bytes) Scaling Factor Units IMPORTANT 100 10 100 USINT 1 1 %FLA The Over Current Inhibit Timer starts after the maximum phase of load current transitions from 0A to 30% of the device’s minimum FLA setting.
PAGE 123
Protective Trip and Warning Functions Chapter 5 . IMPORTANT The L2 Over Current Warning function does not include a time delay feature. Once the Over Current Inhibit Timer has expired, the L2 Over Current Warning indication is instantaneous.
PAGE 124
Chapter 5 Protective Trip and Warning Functions L3 Over Current Trip Delay L3 Over Current Trip Delay (Parameter 282) allows the installer to define the time period a L3 Over Current condition must be present before a trip occurs. It is adjustable from 0.1…25.0 seconds. Table 110 - L3 Over Current Trip Delay (Parameter 282) Default Value 1.0 Minimum Value 0.1 Maximum Value 25.
PAGE 125
Protective Trip and Warning Functions Chapter 5 • L3 Percent FLA (Parameter 49) is greater than the L3 Over Current Warning Level When the L2 Over Current Warning conditions are satisfied, the: • TRIP/WARN LED will flash a yellow 13-short blink pattern • Bit 12 in Current Warning Status (Parameter 10) will set to 1 • Bit 1 in Device Status 0 (Parameter 20) will set to 1 • Any relay outputs configured as a Warning Alarm will close L3 Over Current Warning Level L3 Over Current Warning Level (Parameter 284)
PAGE 126
Chapter 5 Protective Trip and Warning Functions Table 113 - Line Loss Inhibit Time (Parameter 285) Default Value 10 Minimum Value 0 Maximum Value 250 Parameter Type USINT Size (Bytes) 1 Scaling Factor 1 Units Sec L1 Line Loss Trip The E300 Electronic Overload Relay will trip with a L1 Line Loss indication if: • No trip currently exists • L1 Over Current Trip is enabled • L1 Line Loss is activated via the appropriately programmed digital input (see Input Assignments, Parameters 196-201, in Ch
PAGE 127
Protective Trip and Warning Functions IMPORTANT Chapter 5 The Protection Fault State of Relay 0, Relay 1, Relay 2, Digital Module 1 Output Relays, Digital Module 2 Output Relays, Digital Module 3 Output Relays, and Digital Module 4 Output Relays are defined by the respective parameters: • Output PT00 Protection Fault Action (Parameter 304) • Output PT00 Protection Fault Value (Parameter 305) • Output PT01 Protection Fault Action (Parameter 310) • Output PT01 Protection Fault Value (Parameter 311) • Outpu
PAGE 128
Chapter 5 Protective Trip and Warning Functions • L1 Line Loss Warning is enabled • L1 Line Loss is activated via the appropriately programmed digital input (see Input Assignments, Parameters 196-201, in Chapter 3) • Line Loss Inhibit Timer has expired • L1 Percent FLA (Parameter 47) is equal to 0% When the L1 Line Loss Warning conditions are satisfied, the: • TRIP/WARN LED will flash a yellow 14-short blink pattern • Bit 13 in Current Warning Status (Parameter 10) will set to 1 • Bit 1 in Device Status 0
PAGE 129
Protective Trip and Warning Functions IMPORTANT Chapter 5 The Protection Fault State of Relay 0, Relay 1, Relay 2, Digital Module 1 Output Relays, Digital Module 2 Output Relays, Digital Module 3 Output Relays, and Digital Module 4 Output Relays are defined by the respective parameters: • Output PT00 Protection Fault Action (Parameter 304) • Output PT00 Protection Fault Value (Parameter 305) • Output PT01 Protection Fault Action (Parameter 310) • Output PT01 Protection Fault Value (Parameter 311) • Outpu
PAGE 130
Chapter 5 Protective Trip and Warning Functions • L2 Line Loss Warning is enabled • L2 Line Loss is activated via the appropriately programmed digital input (see Input Assignments, Parameters 196-201, in Chapter 3) • Line Loss Inhibit Timer has expired • L2 Percent FLA (Parameter 48) is equal to 0% When the L2 Line Loss Warning conditions are satisfied, the: • TRIP/WARN LED will flash a yellow 15-short blink pattern • Bit 14 in Current Warning Status (Parameter 10) will set to 1 • Bit 1 in Device Status 0
PAGE 131
Protective Trip and Warning Functions IMPORTANT Chapter 5 The Protection Fault State of Relay 0, Relay 1, Relay 2, Digital Module 1 Output Relays, Digital Module 2 Output Relays, Digital Module 3 Output Relays, and Digital Module 4 Output Relays are defined by the respective parameters: • Output PT00 Protection Fault Action (Parameter 304) • Output PT00 Protection Fault Value (Parameter 305) • Output PT01 Protection Fault Action (Parameter 310) • Output PT01 Protection Fault Value (Parameter 311) • Outpu
PAGE 132
Chapter 5 Protective Trip and Warning Functions • L3 Line Loss Warning is enabled • L3 Line Loss is activated via the appropriately programmed digital input (see Input Assignments, Parameters 196-201, in Chapter 3) • Line Loss Inhibit Timer has expired • L3 Percent FLA (Parameter 49) is equal to 0% When the L3 Line Loss Warning conditions are satisfied, the: • TRIP/WARN LED will flash a yellow 16-short blink pattern • Bit 15 in Current Warning Status (Parameter 10) will set to 1 • Bit 1 in Device Status 0
PAGE 133
Protective Trip and Warning Functions Chapter 5 Table 118 - Voltage Trip Enabled (Parameter 184) Bit 15 14 13 12 11 10 9 8 7 6 5 4 3 2 1 0 Function X Under Voltage Trip X Over Voltage Trip X Voltage Imbalance Trip X Phase Rotation Mismatch Trip X Under Frequency Trip X Over Frequency Trip Reserved Reserved Reserved Reserved Reserved Reserved Reserved Reserved Reserved Reserved Table 119 - Voltage Warning Enable (Parameter 190) Bit 15 14 13 12 11 10 9 8 7 6 5 4 3 2
PAGE 134
Chapter 5 Protective Trip and Warning Functions Table 120 - Voltage Trip Status (Parameter 5) Bit 15 14 13 12 11 10 9 8 7 6 5 4 3 2 1 0 Function X Under Voltage Trip X Over Voltage Trip X Voltage Imbalance Trip X Phase Rotation Mismatch Trip X Under Frequency Trip X Over Frequency Trip Reserved Reserved Reserved Reserved Reserved Reserved Reserved Reserved Reserved Reserved Table 121 - Voltage Warning Status (Parameter 11) Bit 15 14 13 12 11 10 9 8 7 6 5 4 3 2 1 0
PAGE 135
Protective Trip and Warning Functions Chapter 5 Under Voltage Protection Electric motors will consume more electric current when the voltage supplied to the motor is lower than the motor name plate rating. This could cause damage to an electric motor over an extended period of time. The E300 Electronic Overload Relay can monitor for this condition with its Under Voltage Trip and Warning function to detect for low voltage levels to minimize motor damage and loss of production.
PAGE 136
Chapter 5 Protective Trip and Warning Functions IMPORTANT The Protection Fault State of Relay 0, Relay 1, Relay 2, Digital Module 1 Output Relays, Digital Module 2 Output Relays, Digital Module 3 Output Relays, and Digital Module 4 Output Relays are defined by the respective parameters: • Output PT00 Protection Fault Action (Parameter 304) • Output PT00 Protection Fault Value (Parameter 305) • Output PT01 Protection Fault Action (Parameter 310) • Output PT01 Protection Fault Value (Parameter 311) • Outpu
PAGE 137
Protective Trip and Warning Functions Chapter 5 Table 124 - Under Voltage Trip Level (Parameter 357) Default Value Minimum Value Maximum Value Parameter Type Size (Bytes) Scaling Factor Units IMPORTANT 100.0 0.0 6553.5 UINT 2 10 Volts The Under Voltage Inhibit Time starts after a phase voltage transitions from 0V to 20V L-L. The E300 Electronic Overload Relay does not begin monitoring for an under voltage condition until the Under Voltage Inhibit Time expires.
PAGE 138
Chapter 5 Protective Trip and Warning Functions IMPORTANT The Under Voltage Warning function does not include a time delay feature. Once the Under Voltage Inhibit Time has expired, the Under Voltage Warning indication is instantaneous. Over Voltage Protection The winding insulation for electric motors will degrade faster when more voltage is supplied to the motor than the motor name plate rating. This could cause damage to an electric motor over an extended period of time.
PAGE 139
Protective Trip and Warning Functions Chapter 5 • Any relay outputs configured as a Trip Alarm will close • Any relay outputs configured as a Normal Relay will be placed in their Protection Fault state (if so programmed) IMPORTANT The Protection Fault State of Relay 0, Relay 1, Relay 2, Digital Module 1 Output Relays, Digital Module 2 Output Relays, Digital Module 3 Output Relays, and Digital Module 4 Output Relays are defined by the respective parameters • Output PT00 Protection Fault Action (Parameter
PAGE 140
Chapter 5 Protective Trip and Warning Functions Table 127 - Over Voltage Trip Level (Parameter 361) Default Value 500.0 Minimum Value 0.0 Maximum Value 6553.5 Parameter Type UINT Size (Bytes) 2 Scaling Factor 10 Units Volts IMPORTANT The Over Voltage Inhibit Time starts after a phase voltage transitions from 0V to 20V L-L. The E300 Electronic Overload Relay does not begin monitoring for an over voltage condition until the Over Voltage Inhibit Time expires.
PAGE 141
Protective Trip and Warning Functions IMPORTANT Chapter 5 The Over Voltage Warning function does not include a time delay feature. Once the Over Voltage Inhibit Time has expired, the Over Voltage Warning indication is instantaneous. Voltage Imbalance Protection A voltage imbalance can be caused by poor power quality and unequal distribution of power.
PAGE 142
Chapter 5 Protective Trip and Warning Functions • • • • • No trip currently exists Voltage Imbalance Trip is enabled Voltage is present Voltage Imbalance Inhibit Time has expired The Voltage Imbalance (Parameter 61) is greater than the Voltage Imbalance Trip Level for a time period greater than the Voltage Imbalance Trip Delay.
PAGE 143
Protective Trip and Warning Functions Chapter 5 Table 130 - Voltage Imbalance Trip Delay (Parameter 366) Default Value 1.0 Minimum Value 0.1 Maximum Value 25.0 Parameter Type USINT Size (Bytes) 1 Scaling Factor 10 Units Sec Voltage Imbalance Trip Level Voltage Imbalance Trip Level (Parameter 367) allows the installer to define the percentage at which the E300 Electronic Overload Relay will trip on a voltage imbalance. It is user-adjustable from 10…100%.
PAGE 144
Chapter 5 Protective Trip and Warning Functions • Any relay outputs configured as a Warning Alarm will close Voltage Imbalance Warning Level Voltage Imbalance Warning Level (Parameter 368) allows the user to define the percentage at which the E300 Electronic Overload Relay will indicate a warning. It is user-adjustable from 10…100%.
PAGE 145
Protective Trip and Warning Functions Chapter 5 Phase Rotation Trip The E300 Electronic Overload Relay will trip with a Phase Rotation indication if: • No trip currently exists • Phase Rotation Trip is enabled • Voltage is present • Phase Rotation Inhibit Time has expired • The measured Voltage Phase Rotation (Parameter 63) does not match the • required Phase Rotation Type (Parameter 364).
PAGE 146
Chapter 5 Protective Trip and Warning Functions Overload Relay will trip on a phase rotation mismatch when this parameter does not match the measured voltage phase rotation. It is user-adjustable, ABC or ACB. Table 134 - Phase Rotation Trip Type (Parameter 364) Default Value 1 = ABC 1 = ABC Range 2 = ACB Parameter Type USINT Size (Bytes) 1 Scaling Factor 1 Units IMPORTANT The Phase Rotation Inhibit Time starts after a phase voltage transitions from 0V to 20V L-L.
PAGE 147
Protective Trip and Warning Functions Chapter 5 Over Frequency Inhibit Time Over Frequency Inhibit Time (Parameter 373) allows the installer to inhibit an over frequency trip and warning from occurring during the motor starting sequence. It is adjustable from 0…250 seconds.
PAGE 148
Chapter 5 Protective Trip and Warning Functions IMPORTANT The Protection Fault State of Relay 0, Relay 1, Relay 2, Digital Module 1 Output Relays, Digital Module 2 Output Relays, Digital Module 3 Output Relays, and Digital Module 4 Output Relays are defined by the respective parameters: • Output PT00 Protection Fault Action (Parameter 304) • Output PT00 Protection Fault Value (Parameter 305) • Output PT01 Protection Fault Action (Parameter 310) • Output PT01 Protection Fault Value (Parameter 311) • Outpu
PAGE 149
Protective Trip and Warning Functions Chapter 5 Table 138 - Under Frequency Trip Level (Parameter 371) Default Value Minimum Value Maximum Value Parameter Type Size (Bytes) Scaling Factor Units IMPORTANT 57 46 65 USINT 1 1 Hz The Under Frequency Inhibit Time starts after a phase voltage transitions from 0V to 20V L-L. The E300 Electronic Overload Relay does not begin monitoring for an under frequency condition until the Under Frequency Inhibit Time expires.
PAGE 150
Chapter 5 Protective Trip and Warning Functions Over Frequency Trip The E300 Electronic Overload Relay will trip with an Over Frequency indication if: • No trip currently exists • Over Frequency Trip is enabled • Voltage is present • Over Frequency Inhibit Time has expired • The voltage frequency is greater than the Over Frequency Trip Level for a time period greater than the Over Frequency Trip Delay.
PAGE 151
Protective Trip and Warning Functions Chapter 5 Over Frequency Trip Delay Over Frequency Trip Delay (Parameter 374) allows the installer to define the time period an over frequency condition must be present before a trip occurs. It is adjustable from 0.1…25.0 seconds. Table 140 - Over Frequency Trip Delay (Parameter 374) Default Value 1.0 Minimum Value 0.1 Maximum Value 25.
PAGE 152
Chapter 5 Protective Trip and Warning Functions • • • • TRIP/WARN LED will flash a yellow 1-long / 6-short blink pattern Bit 5 in Voltage Warning Status (Parameter 11) will set to 1 Bit 1 in Device Status 0 (Parameter 20) will set to 1 Any relay outputs configured as a Warning Alarm will close Over Frequency Warn Level Over Frequency Warn Level (Parameter 376) allows the user to define the frequency at which the E300 Electronic Overload Relay will indicate a warning. It is user-adjustable from 46…65 Hz.
PAGE 153
Protective Trip and Warning Functions • • • • Chapter 5 Under Reactive Power (kVA) Trip/Warning Over Real Power (kVA) Trip/Warning Under Power Factor Trip/Warning Over Power Factor Trip/Warning Power Trip Enable (Parameter 185) and Power Warning Enable (Parameter 191) are used to enable the respective power based protective trip and warning functions.
PAGE 154
Chapter 5 Protective Trip and Warning Functions Table 145 - Power Warning Enable (Parameter 191) Bit 15 14 13 12 11 10 9 8 7 6 5 4 3 2 1 X X X X X X X X X 0 Function X Under kW Warning Over kW Warning Under kVAR Consumed Warning Over kVAR Consumed Warning Under kVAR Generated Warning Over kVAR Generated Warning Under kVA Warning Over kVA Warning Under PF Lagging Warning Over PF Lagging Warning X Under PF Leading Warning X Over PF Leading Warning Reserved Reserved Reserved Reserved Pow
PAGE 155
Protective Trip and Warning Functions Chapter 5 Table 147 - Power Warning Status (Parameter 12) Bit 15 14 13 12 11 10 9 8 7 6 5 4 3 2 1 X X X X X X X X X X X 0 Function X Under kW Warning Over kW Warning Under kVAR Consumed Warning Over kVAR Consumed Warning Under kVAR Generated Warning Over kVAR Generated Warning Under kVA Warning Over kVA Warning Under PF Lagging Warning Over PF Lagging Warning Under PF Leading Warning Over PF Leading Warning Reserved Reserved Reserved Reserved Real Pow
PAGE 156
Chapter 5 Protective Trip and Warning Functions Table 149 - Over kW Inhibit Time (Parameter 382) Default Value 10 Minimum Value 0 Maximum Value 250 Parameter Type USINT Size (Bytes) 1 Scaling Factor 1 Units Sec Under kW Trip The E300 Electronic Overload Relay will trip with an Under kW indication if: • No trip currently exists • Under kW Trip is enabled • Current is present • Voltage is present • Under kW Inhibit Time has expired • The total real power (kW) is less than the Under kW Trip Lev
PAGE 157
Protective Trip and Warning Functions IMPORTANT Chapter 5 The Protection Fault State of Relay 0, Relay 1, Relay 2, Digital Module 1 Output Relays, Digital Module 2 Output Relays, Digital Module 3 Output Relays, and Digital Module 4 Output Relays are defined by the respective parameters: • Output PT00 Protection Fault Action (Parameter 304) • Output PT00 Protection Fault Value (Parameter 305) • Output PT01 Protection Fault Action (Parameter 310) • Output PT01 Protection Fault Value (Parameter 311) • Outpu
PAGE 158
Chapter 5 Protective Trip and Warning Functions Table 151 - UnderkW Trip Level (Parameter 380) Default Value Minimum Value Maximum Value Parameter Type Size (Bytes) Scaling Factor Units IMPORTANT 0.000 0.000 2,000,000.000 DINT 4 1000 kW The Under kW Inhibit Time starts after a phase voltage transitions from 0V to 20V L-L and a phase of load current transitions from 0A to 30% of the device’s minimum FLA setting.
PAGE 159
Protective Trip and Warning Functions Chapter 5 Table 152 - Under kW Warn Level (Parameter 381) Default Value 0.000 Minimum Value 0.000 Maximum Value 2000000.000 Parameter Type DINT Size (Bytes) 4 Scaling Factor 1000 Units kW IMPORTANT The Under kW Warning function does not include a time delay feature. Once the Under kW Inhibit Time has expired, the Under kW Warning indication is instantaneous.
PAGE 160
Chapter 5 Protective Trip and Warning Functions IMPORTANT The Protection Fault State of Relay 0, Relay 1, Relay 2, Digital Module 1 Output Relays, Digital Module 2 Output Relays, Digital Module 3 Output Relays, and Digital Module 4 Output Relays are defined by the respective parameters: • Output PT00 Protection Fault Action (Parameter 304) • Output PT00 Protection Fault Value (Parameter 305) • Output PT01 Protection Fault Action (Parameter 310) • Output PT01 Protection Fault Value (Parameter 311) • Outpu
PAGE 161
Protective Trip and Warning Functions Chapter 5 Table 154 - Over kW Trip Level (Parameter 384) Default Value Minimum Value Maximum Value Parameter Type Size (Bytes) Scaling Factor Units IMPORTANT 0.000 0.000 2000000.000 DINT 4 1000 kW The Over kW Inhibit Time starts after a phase voltage transitions from 0V to 20V L-L and a phase of load current transitions from 0A to 30% of the device’s minimum FLA setting.
PAGE 162
Chapter 5 Protective Trip and Warning Functions IMPORTANT The Over kW Warning function does not include a time delay feature. Once the Over kW Inhibit Time has expired, the Over kW Warning indication is instantaneous. Reactive Power (kVAR) Protection The E300 Electronic Overload Relay has the capability to protect against reactive power (kVAR) for specific applications that require the monitoring of both voltage and current.
PAGE 163
Protective Trip and Warning Functions Chapter 5 Under kVAR Generated Inhibit Time Under kVAR Generated Inhibit Time (Parameter 394) allows the installer to inhibit an under power factor leading trip and warning from occurring during the motor starting sequence. It is adjustable from 0…250 seconds.
PAGE 164
Chapter 5 Protective Trip and Warning Functions • TRIP/WARN LED status indicator will flash a red 2-long / 3-short blink pattern • Bit 2 in Power Trip Status (Parameter 6) will set to 1 • Bit 0 in Device Status 0 (Parameter 20) will set to 1 • Any relay outputs configured as a Trip Relay will open • Any relay outputs configured as a Control Relay will open • Any relay outputs configured as a Trip Alarm will close • Any relay outputs configured as a Normal Relay will be placed in their Protection Fault sta
PAGE 165
Protective Trip and Warning Functions Chapter 5 Under kVAR Consumed Trip Level Under kVAR Consumed Trip Level (Parameter 388) allows the installer to define the reactive power (kVAR) consumed at which the E300 Electronic Overload Relay will trip on an under reactive power (kVAR) consumed. It is user-adjustable from 0…2,000,000 kW. Table 161 - Under kVAR Consumed Trip Level (Parameter 388) Default Value 0.000 Minimum Value 0.000 Maximum Value 2000000.
PAGE 166
Chapter 5 Protective Trip and Warning Functions Table 162 - Under kVAR Consumed Warn Level (Parameter 389) Default Value 0.000 Minimum Value 0.000 Maximum Value 2000000.000 Parameter Type DINT Size (Bytes) 4 Scaling Factor 1000 Units kVAR IMPORTANT The Under kVAR Consumed Warning function does not include a time delay feature. Once the Under kVAR consumed Inhibit Time has expired, the Under kVAR Consumed Warning indication is instantaneous.
PAGE 167
Protective Trip and Warning Functions IMPORTANT Chapter 5 The Protection Fault State of Relay 0, Relay 1, Relay 2, Digital Module 1 Output Relays, Digital Module 2 Output Relays, Digital Module 3 Output Relays, and Digital Module 4 Output Relays are defined by the respective parameters: • Output PT00 Protection Fault Action (Parameter 304) • Output PT00 Protection Fault Value (Parameter 305) • Output PT01 Protection Fault Action (Parameter 310) • Output PT01 Protection Fault Value (Parameter 311) • Outpu
PAGE 168
Chapter 5 Protective Trip and Warning Functions Table 164 - Over kVAR Consumed Trip Level (Parameter 392) Default Value Minimum Value Maximum Value Parameter Type Size (Bytes) Scaling Factor Units IMPORTANT 0.000 0.000 2000000.000 DINT 4 1000 kVAR The Over kVAR Consumed Inhibit Time starts after a phase voltage transitions from 0V to 20V L-L and a phase of load current transitions from 0A to 30% of the device’s minimum FLA setting.
PAGE 169
Protective Trip and Warning Functions IMPORTANT Chapter 5 The Over kVAR Consumed Warning function does not include a time delay feature. Once the Over kVAR Consumed Inhibit Time has expired, the Over kVAR Consumed Warning indication is instantaneous.
PAGE 170
Chapter 5 Protective Trip and Warning Functions IMPORTANT The Protection Fault State of Relay 0, Relay 1, Relay 2, Digital Module 1 Output Relays, Digital Module 2 Output Relays, Digital Module 3 Output Relays, and Digital Module 4 Output Relays are defined by the respective parameters: • Output PT00 Protection Fault Action (Parameter 304) • Output PT00 Protection Fault Value (Parameter 305) • Output PT01 Protection Fault Action (Parameter 310) • Output PT01 Protection Fault Value (Parameter 311) • Outpu
PAGE 171
Protective Trip and Warning Functions Chapter 5 Table 167 - Under kVAR Generated Trip Level (Parameter 396) Default Value 0.000 Minimum Value 0.000 Maximum Value 2000000.000 Parameter Type DINT Size (Bytes) 4 Scaling Factor 1000 Units kVAR IMPORTANT The Under kVAR Generated Inhibit Time starts after a phase voltage transitions from 0V to 20V L-L and a phase of load current transitions from 0A to 30% of the device’s minimum FLA setting.
PAGE 172
Chapter 5 Protective Trip and Warning Functions Table 168 - Under kVAR Generated Warn Level (Parameter 397) Default Value 0.000 Minimum Value 0.000 Maximum Value 2000000.000 Parameter Type DINT Size (Bytes) 4 Scaling Factor 1000 Units kVAR IMPORTANT The Under kVAR Generated Warning function does not include a time delay feature. Once the Under kVAR generated Inhibit Time has expired, the Under kVAR Generated Warning indication is instantaneous.
PAGE 173
Protective Trip and Warning Functions IMPORTANT Chapter 5 The Protection Fault State of Relay 0, Relay 1, Relay 2, Digital Module 1 Output Relays, Digital Module 2 Output Relays, Digital Module 3 Output Relays, and Digital Module 4 Output Relays are defined by the respective parameters: • Output PT00 Protection Fault Action (Parameter 304) • Output PT00 Protection Fault Value (Parameter 305) • Output PT01 Protection Fault Action (Parameter 310) • Output PT01 Protection Fault Value (Parameter 311) • Outpu
PAGE 174
Chapter 5 Protective Trip and Warning Functions Table 170 - Over kVAR Generated Trip Level (Parameter 400) Default Value Minimum Value Maximum Value Parameter Type Size (Bytes) Scaling Factor Units IMPORTANT 0.000 0.000 2000000.000 DINT 4 1000 kVAR The Over kVAR Generated Inhibit Time starts after a phase voltage transitions from 0V to 20V L-L and a phase of load current transitions from 0A to 30% of the device’s minimum FLA setting.
PAGE 175
Protective Trip and Warning Functions IMPORTANT Chapter 5 The Over kVAR Generated Warning function does not include a time delay feature. Once the Over kVAR Generated Inhibit Time has expired, the Over kVAR Generated Warning indication is instantaneous. Apparent Power (kVA) Protection The E300 Electronic Overload Relay has the capability to protect against apparent power (kVA) for specific applications that require the monitoring of both voltage and current.
PAGE 176
Chapter 5 Protective Trip and Warning Functions • • • • • • No trip currently exists Under kVA Trip is enabled Current is present Voltage is present Under kVA Inhibit Time has expired The total apparent power (kVA) is less than the Under kVA Trip Level for a time period greater than the Under kVA Trip Delay.
PAGE 177
Protective Trip and Warning Functions Chapter 5 Table 174 - Under kVA Trip Delay (Parameter 403) Default Value 1.0 Minimum Value 0.1 Maximum Value 25.0 Parameter Type USINT Size (Bytes) 1 Scaling Factor 10 Units Sec Under kVA Trip Level Under kVA Trip Level (Parameter 404) allows the installer to define the apparent power (kVA) at which the E300 Electronic Overload Relay will trip on an under apparent power (kVA). It is user-adjustable from 0…2,000,000 kVA.
PAGE 178
Chapter 5 Protective Trip and Warning Functions • Bit 1 in Device Status 0 (Parameter 20) will set to 1 • Any relay outputs configured as a Warning Alarm will close Under kVA Warn Level Under kVA Warn Level (Parameter 405) allows the user to define the apparent power (kVA) at which the E300 Electronic Overload Relay will indicate a warning. It is user-adjustable from 0…2,000,000 kVA. Table 176 - Under kVA Warn Level (Parameter 405) Default Value 0.000 Minimum Value 0.000 Maximum Value 2,000,000.
PAGE 179
Protective Trip and Warning Functions IMPORTANT Chapter 5 The Protection Fault State of Relay 0, Relay 1, Relay 2, Digital Module 1 Output Relays, Digital Module 2 Output Relays, Digital Module 3 Output Relays, and Digital Module 4 Output Relays are defined by the respective parameters: • Output PT00 Protection Fault Action (Parameter 304) • Output PT00 Protection Fault Value (Parameter 305) • Output PT01 Protection Fault Action (Parameter 310) • Output PT01 Protection Fault Value (Parameter 311) • Outpu
PAGE 180
Chapter 5 Protective Trip and Warning Functions Table 178 - Over kVA Trip Level (Parameter 408) Default Value Minimum Value Maximum Value Parameter Type Size (Bytes) Scaling Factor Units IMPORTANT 0.000 0.000 2,000,000.000 DINT 4 1000 kVA The Over kVA Inhibit Time starts after a phase voltage transitions from 0V to 20V L-L and a phase of load current transitions from 0A to 30% of the device’s minimum FLA setting.
PAGE 181
Protective Trip and Warning Functions IMPORTANT Chapter 5 The Over kVA Warning function does not include a time delay feature. Once the Over kVA Inhibit Time has expired, the Over kVA Warning indication is instantaneous. Power Factor Protection The E300 Electronic Overload Relay has the capability to protect against power factor for specific applications that require the monitoring of both voltage and current.
PAGE 182
Chapter 5 Protective Trip and Warning Functions Under Power Factor Leading Inhibit Time Under Power Factor Leading Inhibit Time (Parameter 418) allows the installer to inhibit an under power factor leading trip and warning from occurring during the motor starting sequence. It is adjustable from 0…250 seconds.
PAGE 183
Protective Trip and Warning Functions Chapter 5 If the E300 Electronic Overload Relay trips on an under power factor lagging, the: • TRIP/WARN LED status indicator will flash a red 2-long / 9-short blink pattern • Bit 8 in Power Trip Status (Parameter 6) will set to 1 • Bit 0 in Device Status 0 (Parameter 20) will set to 1 • Any relay outputs configured as a Trip Relay will open • Any relay outputs configured as a Control Relay will open • Any relay outputs configured as a Trip Alarm will close • Any rela
PAGE 184
Chapter 5 Protective Trip and Warning Functions Under Power Factor Lagging Trip Level Under Power Factor Lagging Trip Level (Parameter 412) allows the installer to define the power factor lagging at which the E300 Electronic Overload Relay will trip on an under power factor lagging. It is user-adjustable from 0…2,000,000 kW.
PAGE 185
Protective Trip and Warning Functions Chapter 5 Table 186 - Under Power Factor Lagging Warn Level (Parameter 413) Default Value -95 Minimum Value -100 Maximum Value 0 Parameter Type SINT Size (Bytes) 1 Scaling Factor 1 Units % IMPORTANT The Under Power Factor Lagging Warning function does not include a time delay feature. Once the Under Power Factor Lagging Inhibit Time has expired, the Under Power Factor Lagging Warning indication is instantaneous.
PAGE 186
Chapter 5 Protective Trip and Warning Functions IMPORTANT The Protection Fault State of Relay 0, Relay 1, Relay 2, Digital Module 1 Output Relays, Digital Module 2 Output Relays, Digital Module 3 Output Relays, and Digital Module 4 Output Relays are defined by the respective parameters: • Output PT00 Protection Fault Action (Parameter 304) • Output PT00 Protection Fault Value (Parameter 305) • Output PT01 Protection Fault Action (Parameter 310) • Output PT01 Protection Fault Value (Parameter 311) • Outpu
PAGE 187
Protective Trip and Warning Functions Chapter 5 Table 188 - Over Power Factor Lagging Trip Level (Parameter 416) Default Value Minimum Value Maximum Value Parameter Type Size (Bytes) Scaling Factor Units IMPORTANT -95 -100 0 SINT 1 1 % The Over Power Factor Lagging Inhibit Time starts after a phase voltage transitions from 0V to 20V L-L and a phase of load current transitions from 0A to 30% of the device’s minimum FLA setting.
PAGE 188
Chapter 5 Protective Trip and Warning Functions IMPORTANT The Over Power Factor Lagging Warning function does not include a time delay feature. Once the Over Power Factor Lagging Inhibit Time has expired, the Over Power Factor Lagging Warning indication is instantaneous.
PAGE 189
Protective Trip and Warning Functions IMPORTANT Chapter 5 The Protection Fault State of Relay 0, Relay 1, Relay 2, Digital Module 1 Output Relays, Digital Module 2 Output Relays, Digital Module 3 Output Relays, and Digital Module 4 Output Relays are defined by the respective parameters: • Output PT00 Protection Fault Action (Parameter 304) • Output PT00 Protection Fault Value (Parameter 305) • Output PT01 Protection Fault Action (Parameter 310) • Output PT01 Protection Fault Value (Parameter 311) • Outpu
PAGE 190
Chapter 5 Protective Trip and Warning Functions Table 191 - Under Power Factor Leading Trip Level (Parameter 420) Default Value Minimum Value Maximum Value Parameter Type Size (Bytes) Scaling Factor Units IMPORTANT 90 100 0 USINT 1 1 % The Under Power Factor Leading Inhibit Time starts after a phase voltage transitions from 0V to 20V L-L and a phase of load current transitions from 0A to 30% of the device’s minimum FLA setting.
PAGE 191
Protective Trip and Warning Functions Chapter 5 Table 192 - Under Power Factor Leading Warn Level (Parameter 421) Default Value 95 Minimum Value 100 Maximum Value 0 Parameter Type USINT Size (Bytes) 1 Scaling Factor 1 Units % IMPORTANT The Under Power Factor Leading Warning function does not include a time delay feature. Once the Under Power Factor Leading Inhibit Time has expired, the Under Power Factor Leading Warning indication is instantaneous.
PAGE 192
Chapter 5 Protective Trip and Warning Functions IMPORTANT The Protection Fault State of Relay 0, Relay 1, Relay 2, Digital Module 1 Output Relays, Digital Module 2 Output Relays, Digital Module 3 Output Relays, and Digital Module 4 Output Relays are defined by the respective parameters: • Output PT00 Protection Fault Action (Parameter 304) • Output PT00 Protection Fault Value (Parameter 305) • Output PT01 Protection Fault Action (Parameter 310) • Output PT01 Protection Fault Value (Parameter 311) • Outpu
PAGE 193
Protective Trip and Warning Functions Chapter 5 Table 194 - Over Power Factor Leading Trip Level (Parameter 424) Default Value Minimum Value Maximum Value Parameter Type Size (Bytes) Scaling Factor Units IMPORTANT 95 100 0 USINT 1 1 % The Over Power Factor Leading Inhibit Time starts after a phase voltage transitions from 0V to 20V L-L and a phase of load current transitions from 0A to 30% of the device’s minimum FLA setting.
PAGE 194
Chapter 5 Protective Trip and Warning Functions I IMPORTANT The Over Power Factor Leading Warning function does not include a time delay feature. Once the Over Power Factor Leading Inhibit Time has expired, the Over Power Factor Leading Warning indication is instantaneous.
PAGE 195
Protective Trip and Warning Functions Chapter 5 Control Trip Status (Parameter 7) and Control Warning Status (Parameter 13) are used to monitor the respective current based protective trip and warning functions.
PAGE 196
Chapter 5 Protective Trip and Warning Functions Table 199 - Control Warning Status (Parameter 13) Bit 15 14 13 12 11 10 9 8 7 6 5 4 3 2 1 0 Function Reserved X X X PTC Warning DeviceLogix Warning Operator Station Warning Reserved Reserved Reserved Reserved X X X X X Option Match Warning Feedback Timeout Warning Expansion Bus Warning Number Of Starts Warning Operating Hours Warning Reserved Reserved Reserved Test Trip The E300 Electronic Overload Relay provides the capability to put th
PAGE 197
Protective Trip and Warning Functions IMPORTANT Chapter 5 The Protection Fault State of Relay 0, Relay 1, Relay 2, Digital Module 1 Output Relays, Digital Module 2 Output Relays, Digital Module 3 Output Relays, and Digital Module 4 Output Relays are defined by the respective parameters: • Output PT00 Protection Fault Action (Parameter 304) • Output PT00 Protection Fault Value (Parameter 305) • Output PT01 Protection Fault Action (Parameter 310) • Output PT01 Protection Fault Value (Parameter 311) • Outpu
PAGE 198
Chapter 5 Protective Trip and Warning Functions • Any relay outputs configured as a Trip Alarm will close • Any relay outputs configured as a Normal Relay will be placed in their Protection Fault state (if so programmed) IMPORTANT The Protection Fault State of Relay 0, Relay 1, Relay 2, Digital Module 1 Output Relays, Digital Module 2 Output Relays, Digital Module 3 Output Relays, and Digital Module 4 Output Relays are defined by the respective parameters: • Output PT00 Protection Fault Action (Parameter
PAGE 199
Protective Trip and Warning Functions Chapter 5 • Any relay outputs configured as a Control Relay will open • Any relay outputs configured as a Trip Alarm will close • Any relay outputs configured as a Normal Relay will be placed in their Protection Fault state (if so programmed) IMPORTANT The Protection Fault State of Relay 0, Relay 1, Relay 2, Digital Module 1 Output Relays, Digital Module 2 Output Relays, Digital Module 3 Output Relays, and Digital Module 4 Output Relays are defined by the respective
PAGE 200
Chapter 5 Protective Trip and Warning Functions If the E300 Electronic Overload Relay trips on a blocked start trip, the following will occur: • The TRIP/WARN LED will flash a red 3-long / 6-short blink pattern • Bit 5 in Control Trip Status (Parameter 7) will set to 1 • Bit 0 in Device Status 0 (Parameter 20) will set to 1 • Any relay outputs configured as a Trip Relay will open • Any relay outputs configured as a Control Relay will open • Any relay outputs configured as a Trip Alarm will close • Any rel
PAGE 201
Protective Trip and Warning Functions Chapter 5 Starts Interval Starts Interval (Parameter 206) is the time that the user must wait between starts. This value is adjustable from 0…3600 seconds.
PAGE 202
Chapter 5 Protective Trip and Warning Functions Preventive Maintenance The E300 Electronic Overload Relay offers preventive maintenance warnings based on the number of start cycles and the number of operating hours. These warnings can be used to alert the user that the number of starts or number of operating hours has been reached, and it is time to perform preventive maintenance.
PAGE 203
Protective Trip and Warning Functions Chapter 5 Table 205 - Starts Counter (Parameter 29) Default Value 0 Minimum Value 0 Maximum Value 65535 Parameter Type UINT Size (Bytes) 2 Scaling Factor 1 Units Operating Hours Warning The E300 Electronic Overload Relay will warn with an operating hours warning indication if: • No warning currently exists • Operating Hours Warning is enabled • The value in Operating Time (Parameter 28) is greater than the value set in Total Operating Hours (Parameter 208
PAGE 204
Chapter 5 Protective Trip and Warning Functions Table 207 - Operating Time (Parameter 28) Default Value 0 Minimum Value 0 Maximum Value 65535 Parameter Type UINT Size (Bytes) 2 Scaling Factor 1 Units Hours Hardware Fault The E300 Electronic Overload Relay continuously monitors the status of the Control, Sensing, and Communication Modules.
PAGE 205
Protective Trip and Warning Functions IMPORTANT Chapter 5 The Protection Fault State of Relay 0, Relay 1, Relay 2, Digital Module 1 Output Relays, Digital Module 2 Output Relays, Digital Module 3 Output Relays, and Digital Module 4 Output Relays are defined by the respective parameters: • Output PT00 Protection Fault Action (Parameter 304) • Output PT00 Protection Fault Value (Parameter 305) • Output PT01 Protection Fault Action (Parameter 310) • Output PT01 Protection Fault Value (Parameter 311) • Outpu
PAGE 206
Chapter 5 Protective Trip and Warning Functions The E300 Electronic Overload Relay will trip with a hardware fault trip indication if: • No trip currently exists • Non-Volatile Storage Fault Trip is enabled • An issue exists in the E300 Electronic Overload Relay’s non-volatile storage If the E300 Electronic Overload Relay trips on a non-volatile storage fault trip, the following will occur: • The TRIP/WARN LED will flash a red 3-long / 14-short blink pattern • Bit 13 in Control Trip Status (Parameter 7) w
PAGE 207
Protective Trip and Warning Functions Chapter 5 capability to put the overload relay into a Test Mode Trip state if motor control center enclosure is in a test position, and the E300 Electronic Overload Relay detects motor current and/or voltage is present. The E300 Electronic Overload Relay will trip with a test mode trip indication if: • No trip currently exists. • Test Mode Trip protection is enabled. • The digital input assigned to read the Test Position feedback is active.
PAGE 208
Chapter 5 Protective Trip and Warning Functions Notes: 208 Rockwell Automation Publication 193-UM015B-EN-P - June 2014
PAGE 209
Chapter 6 Commands Introduction The purpose of this chapter is to provide detailed information regarding the resetting, clearing, and pre-configuration functions of the E300 Electronic Overload Relay. The E300 Electronic Overload Relay provides three types of commands: • Trip Reset • Configuration Preset • Clear Command Trip Reset Trip Reset (Parameter 163) allows the user to reset an E300 Electronic Overload Relay when it is in a tripped state.
PAGE 210
Chapter 6 Commands Table 209 - Config Preset (Parameter 164) Default Value 0 = Ready Range 0 = Ready 1 = Factory Defaults Parameter Type USINT Size (Bytes) 1 Scaling Factor 1 Units Listed below are the available configuration presets and the values for the associated pre-configured configuration values.
PAGE 211
Commands Number Parameter Name 184 TripEnableV Default Units Value 0 Number Parameter Name 322 OutDig1PrFltAct Default Units Value Goto Value Open Number Parameter Name Goto Value Open InAnMod1Ch01Type Default Value Disable 447 InAMod1Ch1Format Eng Units 448 InAMod1C1TmpUnit Degrees C 449 InAMod1C1FiltFrq 17 Hz 450 InAMod1C1OpCktSt Upscale 451 InAnMod1Ch1RTDEn 3-Wire 452 InAMod1C1TripDly 1.
PAGE 212
Chapter 6 Commands Number Parameter Name 227 DigitalMod3Type Default Units Value Ignore 228 DigitalMod4Type Ignore 362 OVWarningLevel 490.0 Volt 483 InAMod2C1TripDly 1.0 229 AnalogMod1Type Ignore 363 PhRotInhibitTime 10 Sec 484 InAMod2C1TripLvl 0 230 AnalogMod2Type Ignore 364 PhaseRotTripType ABC 485 InAMod2C1WarnLvl 0 231 AnalogMod3Type Ignore 365 VIBInhibitTime 10 Sec 486 InAnMod2Ch02Type Disable 232 AnalogMod4Type Ignore 366 VIBTripDelay 1.
PAGE 213
Commands Number Parameter Name Number Parameter Name 274 L3UCWarningLevel Default Units Value 40 % 275 OCInhibitTime 10 Sec 404 UVATripLevel 276 L1OCTripDelay 1.0 Sec 405 UVAWarningLevel 0.000 kVA 526 OutAnMod3Type Disable 277 L1OCTripLevel 100 % 406 OVAInhibitTime 10 Sec 527 OutAnMod3Select Ave %FLA 278 L1OCWarningLevel 90 % 407 OVATripDelay 1.0 Sec 528 OutAnMod3FltActn Zero 279 L2OCTripDelay 1.0 Sec 408 OVATripLevel 0.
PAGE 214
Chapter 6 Commands Table 210 - Clear Command (Parameter 165) Default Value 0 = Ready Range 0 = Ready 1 = Clear Operating Statistics 2 = Clear History Logs 3 = Clear %TCU 4 = Clear kWh 5 = Clear kVARh 6 = Clear kVAh 7 = Clear Max kW Demand 8 = Clear Max kVAR Demand 9 = Clear Max kVA Demand 10 = Clear All Parameter Type USINT Size (Bytes) 1 Scaling Factor 1 Units Clear Operating Statistics When the Clear Operating Statistics command is issued, the E300 Electronic Overload Relay will set the follo
PAGE 215
Commands Chapter 6 Clear %TCU When the Clear %TCU command is issued, the E300 Electronic Overload Relay will set % Thermal Capacity Utilized (Parameter 1) to a value of zero (0).
PAGE 216
Chapter 6 Commands Clear kVAh When the Clear kVAh command is issued, the E300 Electronic Overload Relay will set the following parameters to a value of zero (0): • kVAh x 109 (Parameter 100) • kVAh x 106 (Parameter 101) • kVAh x 103 (Parameter 102) • kVAh x 100 (Parameter 103) • kVAh x 10-3 (Parameter 104) Clear Max kW Demand When the Clear %TCU command is issued, the E300 Electronic Overload Relay will set Max kW Demand (Parameter 106) to a value of zero (0).
PAGE 217
Commands Chapter 6 • kVARh Consumed x 103 (Parameter 87) • kVARh Consumed x 100 (Parameter 88) • kVARh Consumed x 10-3 (Parameter 89) • kVARh Generated x 109 (Parameter 90) • kVARh Generated x 106 (Parameter 91) • kVARh Generated x 103 (Parameter 92) • kVARh Generated x 100 (Parameter 93) • kVARh Generated x 10-3 (Parameter 94) • kVARh Net x 109 (Parameter 95) • kVARh Net x 106 (Parameter 96) • kVARh Net x 103 (Parameter 97) • kVARh Net x 100 (Parameter 98) • kVARh Net x 10-3 (Parameter 99) • kVAh x 109 (
PAGE 218
Chapter 6 Commands Notes: 218 Rockwell Automation Publication 193-UM015B-EN-P - June 2014
PAGE 219
Chapter 7 Metering and Diagnostics Introduction The purpose of this chapter is to provide detailed information regarding the metering and diagnostic information that the E300 Electronic Overload Relay generates.
PAGE 220
Chapter 7 Metering and Diagnostics Table 211 - Percent Thermal Capacity Utilization (Parameter 1) Default Value Minimum Value Maximum Value Parameter Type Size (Bytes) Scaling Factor Units 0 0 100 USINT 1 1 % Time to Trip When the measured motor current exceeds the trip rating of the E300 Electronic Overload Relay, Overload Time to Trip (Parameter 2) indicates the estimated time remaining before an overload trip occurs.
PAGE 221
Metering and Diagnostics Chapter 7 Current Trip Status Current Trip Status (Parameter 4) reports the status of the current based protective trip functions.
PAGE 222
Chapter 7 Metering and Diagnostics Voltage Trip Status Voltage Trip Status (Parameter 5) reports the status of the voltage-based protective trip functions.
PAGE 223
Metering and Diagnostics Chapter 7 Power Trip Status Power Trip Status (Parameter 6) reports the status of the voltage-based protective trip functions.
PAGE 224
Chapter 7 Metering and Diagnostics Table 217 - Control Trip Status (Parameter 7) Bit 15 14 13 12 11 10 9 8 7 6 5 4 3 2 1 X X X X X X X X X X X X 0 Function X Test Trip PTC Trip DeviceLogix Trip Operator Station Trip Remote Trip Blocked Start Trip Hardware Fault Trip Configuration Trip Option Match Trip Feedback Timeout Trip Expansion Bus Trip Reserved Reserved Non-Volatile Memory Trip Test Mode Trip Enable Reserved Current Warning Status Current Warning Status (Parameter 10) reports the
PAGE 225
Metering and Diagnostics Chapter 7 Voltage Warning Status Voltage Warning Status (Parameter 11) reports the status of the control based protective warning functions.
PAGE 226
Chapter 7 Metering and Diagnostics Power Warning Status Power Warning Status (Parameter 12) reports the status of the control based protective warning functions.
PAGE 227
Metering and Diagnostics Chapter 7 Input Status 0 Input Status 0 (Parameter 16) reports the state of the digital inputs on the E300 Electronic Overload Relay Control Module.
PAGE 228
Chapter 7 Metering and Diagnostics Output Status Output Status (Parameter 18) reports the state of the relay outputs on the E300 Electronic Overload Relay Control Module and Digital Expansion Modules.
PAGE 229
Metering and Diagnostics Chapter 7 Operator Station Status Operator Station Status (Parameter 19) reports the state of the E300 Electronic Overload Relay Operator Station input buttons and output LEDs.
PAGE 230
Chapter 7 Metering and Diagnostics Device Status 0 Device Status 0 (Parameter 20) reports the general status of the E300 Electronic Overload Relay and the sensing capabilities that are present.
PAGE 231
Metering and Diagnostics Chapter 7 Device Status 1 Device Status 1 (Parameter 21) reports the specific features of the E300 Electronic Overload Relay Control and Sensing Modules, it reports which Expansion Digital Modules Analog Modules are present on the E300 Electronic Overload Relay Expansion Bus.
PAGE 232
Chapter 7 Metering and Diagnostics Control Module ID Control Module ID (Parameter 23) identifies which specific Control Module is present in the E300 Electronic Overload Relay system.
PAGE 233
Metering and Diagnostics Chapter 7 Operator Station ID Operator Station ID (Parameter 25) identifies which specific Operator Station is present on the Expansion Bus of the E300 Electronic Overload Relay system.
PAGE 234
Chapter 7 Metering and Diagnostics Operating Time Operating Time (Parameter 28) represents the number hours that a motor has been running. This value can be reset to zero using the Clear Command (Parameter 165) function Clear Operating Statistics. Table 233 - Operating Time (Parameter 28) Default Value Minimum Value Maximum Value Parameter Type Size (Bytes) Scaling Factor Units 0 0 65535 UINT 2 1 Hours Starts Counter Starts Counter (Parameter 29) represents the number of times a motor has been started.
PAGE 235
Metering and Diagnostics Chapter 7 Time to Start Time to Start (Parameter 31) reports the amount of time remaining until a new start can be issued. If the Time to Start time has elapsed, this parameter will report zero until the next Blocked Start trip occurs.
PAGE 236
Chapter 7 Metering and Diagnostics Day Day (Parameter 34) reports the day in the virtual real-time clock of the E300 Electronic Overload Relay. Table 239 - Day (Parameter 34) Default Value Minimum Value Maximum Value Parameter Type Size (Bytes) Scaling Factor Units 0 0 31 UINT 2 1 Hour Hour (Parameter 35) reports the hour in the virtual real-time clock of the E300 Electronic Overload Relay.
PAGE 237
Metering and Diagnostics Chapter 7 Second Second (Parameter 37) reports the second in the virtual real-time clock of the E300 Electronic Overload Relay. Table 242 - Second (Parameter 37) Default Value Minimum Value Maximum Value Parameter Type Size (Bytes) Scaling Factor Units 0 0 60 UINT 2 1 Invalid Configuration Parameter Invalid Configuration Parameter (Parameter 38) reports the parameter number that is causing a configuration trip in the E300 Electronic Overload Relay.
PAGE 238
Chapter 7 Metering and Diagnostics Mismatch Status Mismatch Status (Parameter 40) reports the module that is causing a mismatch trip or warning in the E300 Electronic Overload Relay. Refer to Chapter 3 for more information on a mismatch fault.
PAGE 239
Metering and Diagnostics Chapter 7 Table 246 - L1 Current (Parameter 43) Default Value Minimum Value Maximum Value Parameter Type Size (Bytes) Scaling Factor Units 0.00 0.00 20000000.00 DINT 4 100 Amps L2 Current L2 Current (Parameter 44) reports the current in Amperes flowing through the L2 and T2 power terminals of the E300 Electronic Overload Relay Sensing Module. Table 247 - L2 Current (Parameter 44) Default Value Minimum Value Maximum Value Parameter Type Size (Bytes) Scaling Factor Units 0.00 0.
PAGE 240
Chapter 7 Metering and Diagnostics When single or three phase (Parameter 176) is set to single phase, average current is calculated as follows: Average Current = (L1 Current + L2 Current) / 2 Table 249 - Average Current (Parameter 46) Default Value Minimum Value Maximum Value Parameter Type Size (Bytes) Scaling Factor Units 0.00 0.00 20000000.
PAGE 241
Metering and Diagnostics Chapter 7 L3 Percent FLA L3 Percent FLA (Parameter 49) reports the L3 current in comparison to the active Full Load Amps programmed in FLA (Parameter 171) and FLA2 (Parameter 177). L3 Percent FLA = L3 Current / Full Load Amps Table 252 - L3 Percent FLA (Parameter 49) Default Value Minimum Value Maximum Value Parameter Type Size (Bytes) Scaling Factor Units 0.0 0.0 1000.
PAGE 242
Chapter 7 Metering and Diagnostics Current Imbalance Current Imbalance (Parameter 52) reports the percentage of uneven current consumption in the monitored power system.
PAGE 243
Metering and Diagnostics Chapter 7 L2-L3 Voltage L2-L3 Voltage (Parameter 54) reports the voltage in volts in reference to the T2 and T3 power terminals of the E300 Electronic Overload Relay Sensing Module. Table 257 - L2-L3 Voltage (Parameter 54) Default Value 0.0 Minimum Value 0.0 Maximum Value 6553.
PAGE 244
Chapter 7 Metering and Diagnostics Size (Bytes) 2 Scaling Factor 10 Units Volts L1-N Voltage L1-N Voltage (Parameter 57) reports the voltage in volts in reference to the T1 power terminal of the E300 Electronic Overload Relay Sensing Module. Table 261 - L1-N Voltage (Parameter 57) Default Value 0.0 Minimum Value 0.0 Maximum Value 6553.
PAGE 245
Metering and Diagnostics Size (Bytes) 2 Scaling Factor 10 Units Volts Chapter 7 Average L-N Voltage Average L-N Voltage (Parameter 60) reports the average voltage of the monitored L-N voltages.
PAGE 246
Chapter 7 Metering and Diagnostics Size (Bytes) 2 Scaling Factor 1 Units % Frequency Frequency (Parameter 62) reports the voltage frequency in Hertz of the monitored power system from the E300 Electronic Overload Relay Sensing Module. Table 266 - Frequency (Parameter 62) Default Value 0.0 Minimum Value 0.0 Maximum Value 74.
PAGE 247
Metering and Diagnostics Chapter 7 Power Scale For large medium voltage based power systems, it may be more convenient for the user to view the real-time power information (Parameters 64-75) in terms of Megawatts instead of Kilowatts. Power Scale (Parameter 377) allows the E300 Electronic Overload Relay to display the values of Parameters 64-75 as Kilowatts or Megawatts.
PAGE 248
Chapter 7 Metering and Diagnostics Table 270 - L2 Real Power (Parameter 65) Default Value 0.000 Minimum Value -2000000.000 Maximum Value 2000000.000 Parameter Type DINT Size (Bytes) 4 Scaling Factor 1000 Units kW or MW L3 Real Power L3 Real Power (Parameter 66) reports the real power for line 3 in kW or MW depending on the configuration value for Power Scale (Parameter 377). When Voltage Mode (Parameter 352) is set to any Delta base setting, L3 Real Power is set to 0.
PAGE 249
Metering and Diagnostics Chapter 7 Table 272 - Total Real Power (Parameter 67) Default Value 0.000 Minimum Value -2000000.000 Maximum Value 2000000.000 Parameter Type DINT Size (Bytes) 4 Scaling Factor 1000 Units kW or MW L1 Reactive Power L1 Reactive Power (Parameter 68) reports the reactive power for line 1 in kVAR or MVAR depending on the configuration value for Power Scale (Parameter 377). When Voltage Mode (Parameter 352) is set to any Delta base setting, L1 Reactive Power is set to 0.
PAGE 250
Chapter 7 Metering and Diagnostics L3 Reactive Power L3 Reactive Power (Parameter 70) reports the reactive power for line 3 in kVAR or MVAR depending on the configuration value for Power Scale (Parameter 377). When Voltage Mode (Parameter 352) is set to any Delta base setting, L3 Reactive Power is set to 0. When Single or Three Phase (Parameter 176) is set to Single Phase, L3 Reactive Power is set to 0. Table 275 - L3 Reactive Power (Parameter 70) Default Value 0.000 Minimum Value -2000000.
PAGE 251
Metering and Diagnostics Chapter 7 When Voltage Mode (Parameter 352) is set to any Delta base setting, L1 Apparent Power is set to 0. Table 277 - L1 Apparent Power (Parameter 72) Default Value 0.000 Minimum Value 0.000 Maximum Value 2000000.000 Parameter Type DINT Size (Bytes) 4 Scaling Factor 1000 Units kVA or MVA L2 Apparent Power L2 Apparent Power (Parameter 73) reports the apparent power for line 2 in kVA or MVA depending on the configuration value for Power Scale (Parameter 377).
PAGE 252
Chapter 7 Metering and Diagnostics Total Apparent Power Total Apparent Power (Parameter 75) reports the total apparent power of the monitored power conductors in kVA or MVA depending on the configuration value for Power Scale (Parameter 377).
PAGE 253
Metering and Diagnostics Chapter 7 Table 282 - L2 Power Factor (Parameter 77) Default Value 0.0 Minimum Value -100.0 Maximum Value 100.0 Parameter Type INT Size (Bytes) 2 Scaling Factor 10 Units % L3 Power Factor L3 Power Factor (Parameter 78) reports the power factor for line 3 in percentage. When Voltage Mode (Parameter 352) is set to any Delta base setting, L3 Power Factor is set to 0. When Single or Three Phase (Parameter 176) is set to Single Phase, L3 power factor is set to 0.
PAGE 254
Chapter 7 Metering and Diagnostics Units Energy Monitor % The E300 Electronic Overload Relay’s energy monitor diagnostics provides information on the electrical energy being consumed by the load. The energy diagnostics include kWh, kVARh, kVAh, kW Demand, kVAR Demand, and kVA Demand. kWh 109 kWh 109 (Parameter 80) reports a component of total real energy (kWh). Multiply this value by 109 and add to the other kWh parameters. Represents XXX,000,000,000.
PAGE 255
Metering and Diagnostics Chapter 7 kWh 103 kWh 103 (Parameter 82) reports a component of total real energy (kWh). Multiply this value by 103 and add to the other kWh parameters. Represents 000,000,XXX,000.000 kWh Table 287 - kWh x 10E3 (Parameter 82) Default Value 0 Minimum Value -999 Maximum Value 999 Parameter Type INT Size (Bytes) 2 Scaling Factor 1 Units kWh 100 kWh 100 (Parameter 83) reports a component of total real energy (kWh).
PAGE 256
Chapter 7 Metering and Diagnostics Size (Bytes) 2 Scaling Factor 1 Units kVARh Consumed 109 kVARh Consumed 109 (Parameter 85) reports a component of total reactive energy consumed (kVARh). Multiply this value by 109 and add to the other kVARh Consumed parameters. Represents XXX,000,000,000.
PAGE 257
Metering and Diagnostics Chapter 7 kVARh Consumed 103 kVARh Consumed 103 (Parameter 87) reports a component of total reactive energy consumed (kVARh). Multiply this value by 103 and add to the other kVARh Consumed parameters. Represents 000,000,XXX,000.
PAGE 258
Chapter 7 Metering and Diagnostics Minimum Value -999 Maximum Value 999 Parameter Type INT Size (Bytes) 2 Scaling Factor 1 Units kVARh Generated 109 kVARh Generated 109 (Parameter 90) reports a component of total reactive energy generated (kVARh). Multiply this value by 109 and add to the other kVARh Generated parameters. Represents XXX,000,000,000.
PAGE 259
Metering and Diagnostics Chapter 7 kVARh Generated 103 kVARh Generated 103 (Parameter 92) reports a component of total reactive energy generated (kVARh). Multiply this value by 103 and add to the other kVARh Generated parameters. Represents 000,000,XXX,000.
PAGE 260
Chapter 7 Metering and Diagnostics Table 299 - kVARh Generated x 10E-3 (Parameter 94) Default Value 0 Minimum Value -999 Maximum Value 999 Parameter Type INT Size (Bytes) 2 Scaling Factor 1 Units kVARh Net 109 kVARh Net 109 (Parameter 95) reports a component of total reactive energy net (kVARh). Multiply this value by 109 and add to the other kVARh Net parameters. Represents XXX,000,000,000.
PAGE 261
Metering and Diagnostics Chapter 7 kVARh Net 103 kVARh Net 103 (Parameter 97) reports a component of total reactive energy net (kVARh). Multiply this value by 103 and add to the other kVARh Net parameters. Represents 000,000,XXX,000.000 kVARh Table 302 - kVARh Net x 10E3 (Parameter 97) Default Value 0 Minimum Value -999 Maximum Value 999 Parameter Type INT Size (Bytes) 2 Scaling Factor 1 Units kVARh Net 100 kVARh Net 100 (Parameter 98) reports a component of total reactive energy net (kVARh).
PAGE 262
Chapter 7 Metering and Diagnostics Table 304 - kVARh Net x 10E-3 (Parameter 99) Default Value 0 Minimum Value -999 Maximum Value 999 Parameter Type INT Size (Bytes) 2 Scaling Factor 1 Units kVAh 109 kVAh 109 (Parameter 100) reports a component of total apparent energy (kVAh). Multiply this value by 109 and add to the other kVAh parameters. Represents XXX,000,000,000.
PAGE 263
Metering and Diagnostics Chapter 7 kVAh 103 kVAh 103 (Parameter 102) reports a component of total apparent energy (kVAh). Multiply this value by 103 and add to the other kVAh parameters. Represents 000,000,XXX,000.000 kVAh Table 307 - kVAh x 10E3 (Parameter 102) Default Value 0 Minimum Value -999 Maximum Value 999 Parameter Type INT Size (Bytes) 2 Scaling Factor 1 Units kVAh 100 kVAh 100 (Parameter 103) reports a component of total apparent energy (kVAh).
PAGE 264
Chapter 7 Metering and Diagnostics Maximum Value 999 Parameter Type INT Size (Bytes) 2 Scaling Factor 1 Units kW Demand kW Demand (Parameter 105) reports the average real energy usage in kW over a defined period of time. Table 310 - kW Demand (Parameter 105) Default Value 0.000 Minimum Value -2000000.000 Maximum Value 2000000.
PAGE 265
Metering and Diagnostics Maximum Value 2000000.000 Parameter Type DINT Size (Bytes) 4 Scaling Factor 1000 Units kVAR Chapter 7 Max kVAR Demand Max kVAR Demand (Parameter 108) reports the maximum kVAR Demand since the last Max kVAR Demand Reset command. Table 313 - Max kVAR Demand (Parameter 108) Default Value 0.000 Minimum Value -2000000.000 Maximum Value 2000000.
PAGE 266
Chapter 7 Metering and Diagnostics Trip / Warning History Parameter Type DINT Size (Bytes) 4 Scaling Factor 1000 Units kVA The E300 Electronic Overload Relay provides a trip and warning history in which the last five trips and last five warnings are recorded into non-volatile storage. A mask is available to limit which trip and warning events are logged to the history's memory.
PAGE 267
Metering and Diagnostics Trip History Code Description 26 Sensing Module output enable open 27 Sensing Module missing interrupts 28 Sensing Module not calibrated 29 Sensing Module frame type failure 30 Sensing Module flash configuration failure 31 Sensing Module detected an overrun error 32 Sensing Module is not responding 33 Total Real Power(kW)is below trip level 34 Total Real Power(kW)has exceeded trip level 35 Under Total Reactive Power Consumed (+kVAR) condition detected 36 Over
PAGE 268
Chapter 7 Metering and Diagnostics Trip History Code Description 74 Input Channel 00 on Analog Module 4 exceeded its Trip Level 75 Input Channel 01 on Analog Module 4 exceeded its Trip Level 76 Input Channel 02 on Analog Module 4 exceeded its Trip Level 77 External NVS Chip has detected communication timeout error 78 External NVS Chip has detected a CRC error 79 External NVS Chip has detected data out of range 81 Digital Expansion Module 1 is not operating properly 82 Digital Expansion Mo
PAGE 269
Metering and Diagnostics Chapter 7 Table 317 - Current Trip History Mask (Parameter 139) Bit 15 14 13 12 11 10 9 8 7 6 5 4 3 2 1 X X X X X X X X X X X X X X X 0 Function X Overload Trip Phase Loss Trip Ground Fault Trip Stall Trip Jam Trip Underload Trip Current Imbalance Trip L1 Under Current Trip L2 Under Current Trip L3 Under Current Trip L1 Over Current Trip L2 Over Current Trip L3 Over Current Trip L1 Line Loss Trip L2 Line Loss Trip L3 Line Loss Trip Voltage Trip History Mask Voltag
PAGE 270
Chapter 7 Metering and Diagnostics Power Trip History Mask Power Trip History Mask (Parameter 141) allows users to select which power based trip events are recorded in the trip history.
PAGE 271
Metering and Diagnostics Chapter 7 Table 320 - Control Trip History Mask (Parameter 142) Bit 15 14 13 12 11 10 9 8 7 6 5 4 3 2 1 0 Function X Test Trip X X X X X X X X X PTC Trip DeviceLogix Trip Operator Station Trip Remote Trip Blocked Start Trip Hardware Fault Trip Configuration Trip Option Match Trip Feedback Timeout Trip X Expansion Bus Trip Reserved Reserved X Non-Volatile Memory Trip X Test Mode Trip Reserved Warning History When the E300 Electronic Overload Relay issue a w
PAGE 272
Chapter 7 Metering and Diagnostics Warning History Code Description 272 17 Line to Line Under-Voltage condition detected 18 Line to Line Over-Voltage condition detected 19 Phase to phase voltage imbalance detected 20 The unit detects the supply voltage phases are rotated 21 Line voltage frequency is below the warning level 22 Line voltage frequency has exceeded warning level 33 Total Real Power (kW)is below warning level 34 Total Real Power (kW)has exceeded warning level 35 Under Reacti
PAGE 273
Metering and Diagnostics Chapter 7 Warning History Code Description 88 Analog Expansion Module 4 is not operating properly 90 Control Module installed does not match the expected type 91 Sensing Module installed does not match the expected type 92 Comms Module installed does not match the expected type 93 Operator Station installed does not match expected type 94 Digital Module installed does not match the expected type 95 Analog Module installed does not match the expected type 98 A hardwa
PAGE 274
Chapter 7 Metering and Diagnostics Table 323 - Voltage Warning History Mask (Parameter 146) Bit 15 14 13 12 11 10 9 8 7 6 5 4 3 2 1 0 X X X Function Under Voltage Warning Over Voltage Warning Voltage Imbalance Warning X Phase Rotation Warning X Under Frequency Warning X Over Frequency Warning Reserved Reserved Reserved Reserved Reserved Reserved Reserved Reserved Reserved Reserved Power Warning History Mask Power Warning History Mask (Parameter 147) allows users to select which pow
PAGE 275
Metering and Diagnostics Chapter 7 Control Warning History Mask Control Warning History Mask (Parameter 148) allows users to select which control based warning events are recorded in the warning history.
PAGE 276
Chapter 7 Metering and Diagnostics Trip Snapshot L2-L3 Voltage Trip Snapshot L2-L3 Voltage (Parameter 157) reports the voltage in volts in reference to the T2 and T3 power terminals of the E300 Electronic Overload Relay Sensing Module at the time of the most recent trip event. Table 327 - Trip Snapshot L2-L3 Voltage (Parameter 157) Default Value 0.0 Minimum Value 0.0 Maximum Value 6553.
PAGE 277
Metering and Diagnostics Chapter 7 Trip Snapshot Total Reactive Power Trip Snapshot Total Reactive Power (Parameter 160) reports the total Reactive power of the monitored power conductors in kVAR at the time of the most recent trip event. Table 330 - Trip Snapshot Total Reactive Power (Parameter 160) Default Value 0.000 Minimum Value -2000000.000 Maximum Value 2000000.
PAGE 278
Chapter 7 278 Metering and Diagnostics Rockwell Automation Publication 193-UM015B-EN-P - June 2014
PAGE 279
Chapter 8 EtherNet/IP Communications Introduction The purpose of this chapter is to provide the necessary instructions to successfully connect the E300™ Electronic Overload Relay EtherNet/IP Communication Module (Catalog Number 193-ECM-ETR) to an Ethernet network and configure it to communicate to an EtherNet/IP scanner such as an Allen-Bradley Logix controller.
PAGE 280
Chapter 8 EtherNet/IP Communications Rockwell Automation also offers a line of managed and unmanaged Allen-Bradley Ethernet Switches with its Stratix™ family of Ethernet switches. Refer to http://ab.rockwellautomation.com/Networks-and-Communications/ Ethernet-IP-Infrastructure for more information.
PAGE 281
EtherNet/IP Communications Determining Network Parameters Chapter 8 To operate an EtherNet/IP network, you must define these parameters. Table 333 - EtherNet/IP Network Parameters Network Parameter Description IP Address The IP address uniquely identifies the module. The IP address is in the form xxx.xxx.xxx.xxx where each xxx is a number from 0...255. Do not use the following IP addresses, as these are reserved values: • 0.0.0.1...0.255.255.255 • 127.0.0.0...127.255.255.255 • 224.255.255.255...255.
PAGE 282
Chapter 8 EtherNet/IP Communications Setting the IP Network Address The E300 Electronic Overload Relay EtherNet/IP Communication Module ships with DHCP enabled. You can set the network Internet Protocol (IP) address by using: • The EtherNet/IP node address selection switches • A Bootstrap Protocol (BOOTP)/Dynamic Host Configuration Protocol (DHCP) server (e.g.
PAGE 283
EtherNet/IP Communications Chapter 8 Assign Network Parameters via the BOOTP/ DHCP Utility By default, the E300 Electronic Overload Relay EtherNet/IP Communication Module is DHCP Enabled. The BOOTP/DHCP utility is a standalone program that is located in the BOOTPDHCP Server folder accessed from the Start menu.
PAGE 284
Chapter 8 EtherNet/IP Communications The New Entry window appears with the module's Ethernet Address (MAC). 6. Type the IP address, host name, and a module description. 7. Click OK. 8. Cycle power to the E300 Electronic Overload Relay EtherNet/IP Communication Module. 9. To permanently assign this configuration to the module: Select the module in the Relation List panel and click Disable BOOTP/DHCP. When module power is cycled, it uses the assigned configuration and does not issue a DHCP request.
PAGE 285
EtherNet/IP Communications Chapter 8 Assign Network Parameters Via a Web Browser & MAC Scanner Software In the event that a user does not have access to a DHCP software utility, a user can assign network parameters via a web browser (e.g., Microsoft® Internet Explorer) and Media Access Control (MAC) scanner software (e.g., MAC Scanner from Colasoft® - http://www.colasoft.com/). Follow these steps to configure the module using this method. 1.
PAGE 286
Chapter 8 EtherNet/IP Communications If the Rockwell Automation DHCP server is used in an uplinked subnet where an enterprise DHCP server exists, a module may get an address from the enterprise server before the Rockwell Automation utility even sees the module. In this case, disconnect the uplink to set the address and configure the module to retain its static address before reconnecting to the uplink. This is not a problem if you have node names configured in the module and leave DHCP enabled.
PAGE 287
EtherNet/IP Communications Chapter 8 5. Enable the Web Server Control and press Apply Changes Duplicate IP Address Detection When you change the IP address or connect the module to an EtherNet/IP network, the module checks to make sure that the IP address assigned to this module does not match the address of any other network device.
PAGE 288
Chapter 8 EtherNet/IP Communications Table 335 - Device Conflict over Duplicate IP Addresses DNS Addressing If then both modules support duplicate IP address detection, the first started module uses and retains its IP address. The other module will detect a conflict, give up the IP address and enter conflict mode. both modules support duplicate IP address detection and are started at roughly the same time, one of the modules surrenders the IP address and enters conflict mode.
PAGE 289
EtherNet/IP Communications Chapter 8 Download the EDS File Embedded in the Module The EDS file for the E300 Electronic Overload Relay EtherNet/IP Communication Module is embedded within the module. Using RSLinx Classic, the user can install the E300 Electronic Overload Relay EtherNet/IP Communication Module's EDS file from the RSLinx Classic RSWho screen using these steps: 1. Open RSLinx Classic and browse the EtherNet/IP network that has the E300 Electronic Overload Relay.
PAGE 290
Chapter 8 EtherNet/IP Communications 3. When finished, RSLinx Classic will recognize the newly registered E300 Electronic Overload Relay EtherNet/IP Communication Module. From the EDS File Download Site The EDS file for the E300 Electronic Overload Relay EtherNet/IP Communication Module can also be downloaded from the Allen-Bradley EDS File download site. Using a web browser on the personal computer that is connected to the internet, a user can download the EDS file by following these steps: 1.
PAGE 291
EtherNet/IP Communications Chapter 8 3. Locate the EDS file for the E300 Electronic Overload Relay EtherNet/IP Communication Module and download it to the personal computer. 4. Start the EDS Hardware Installation Tool located at Start>Programs>Rockwell Software>RSLinx Tools and Add a new device 5. Using the EDS Wizard, install the downloaded E300 Electronic Overload Relay EtherNet/IP Communication Module EDS file.
PAGE 292
Chapter 8 EtherNet/IP Communications 6. When finished, RSLinx Classic will recognize the newly registered E300 Electronic Overload Relay EtherNet/IP Communication Module. View & Configure Parameters The web server in the E300 Electronic Overload Relay EtherNet/IP Communication Module when enabled is able to view and configure parameters for the E300 Electronic Overload Relay.
PAGE 293
EtherNet/IP Communications Chapter 8 2. Navigate to the Parameters folder and select a parameter group. The example below shows the information from the Current Monitoring parameters. 3. To increase the update rate of the data being viewed, enter a faster update time in the refresh rate box shown below: 4. E300 Electronic Overload Relay EtherNet/IP Communication Module web page displays up to 17 parameters per web page.
PAGE 294
Chapter 8 EtherNet/IP Communications 1. Select a parameter group that contains programmable parameters, then click the Edit button. The value options will appear. 2. Click the down arrow on the pull-down boxes to adjust fixed values and/or enter numerical values in the fields without an arrow to adjust the values. 3. Click Apply once all parameter edits have been completed. The E300 Electronic Overload Relay EtherNet/IP Communication Module will download the new parameter values to the device.
PAGE 295
EtherNet/IP Communications Chapter 8 4. A confirmation window will appear. Press OK. NOTE: If the user attempts to edit a configuration parameter when a Class 1 EtherNet/IP connection exists between an EtherNet/IP scanner and the E300 Electronic Overload Relay EtherNet/IP Communication Module, a message similar to the one shown below will appear when the Apply button is pressed.
PAGE 296
Chapter 8 EtherNet/IP Communications Logix Configuration with Add-On Profile An Add-On Profile is available for the E300 Electronic Overload Relay EtherNet/IP Communication Module and can be used with RSLogix 5000 version 17 and higher and Studio 5000 version 21 and higher. The profile can be downloaded from: http://compatibility.rockwellautomation.com/Pages/ MultiProductFindDownloads.
PAGE 297
EtherNet/IP Communications Chapter 8 3. Enter a name and the IP address for the E300 Electronic Overload Relay EtherNet/IP Communication Module. The name will create tags in RSLogix 5000 or Studio 5000 that can be used to read and write data from the E300 Electronic Overload Relay EtherNet/IP Communication Module. 4. Select Change to select the modules and accessories of the E300 Electronic Overload Relay system. 5.
PAGE 298
Chapter 8 EtherNet/IP Communications 6. Right click on the Expansion Bus to add the specific Expansion Bus accessories for the E300 Electronic Overload Relay system and select their specific Option Match action. When finished, press OK. 7. Configure the E300 Electronic Overload Relay system's Operating Mode and associated relay output assignments. Refer to Chapter 4 for more information regarding Operating Modes. 8. The E300 Electronic Overload Relay allows the user to configure up to 8 Datalinks.
PAGE 299
EtherNet/IP Communications Chapter 8 9. Next, set the overload protection configuration parameters for your specific motor application by selecting Protection. When finished, press OK to complete the addition of the E300 Electronic Overload Relay to the Logix system. 10. To configure the other protection configuration parameters, navigate to the configuration tags of the newly added E300 Electronic Overload Relay.
PAGE 300
Chapter 8 EtherNet/IP Communications 11. Download the project to the Logix controller, and place the controller into Run Mode. The E300 Electronic Overload Relay is actively communicating with the Logix controller. 12. To access the data provided by the E300 Electronic Overload Relay EtherNet/IP Communication Module, navigate to input tags created by the Add-On Profile.
PAGE 301
EtherNet/IP Communications Chapter 8 13. To control the output relays or remote reset the E300 Electronic Overload Relay navigate to the output tags created by the Add-On Profile. Logix Configuration with a Generic Profile An existing project can be used or a new project can be created to configure EtherNet/IP I/O Messaging. After the Logix controller has been configured, the E300 Electronic Overload Relay EtherNet/IP Communication Module must be added to the I/O configuration.
PAGE 302
Chapter 8 EtherNet/IP Communications 2. Select the Generic Ethernet Module, then click Create. 3. Enter a name and the IP address for the E300 Electronic Overload Relay EtherNet/IP Communication Module. The name will create tags in RSLogix 5000 or Studio 5000 that can be used to read and write data from the E300 Electronic Overload Relay EtherNet/IP Communication Module. 4. Select Data-DINT for the Comm Format.
PAGE 303
EtherNet/IP Communications Chapter 8 5. To access the data provided by the E300 Electronic Overload Relay EtherNet/IP Communication Module, navigate to input tags created by the Generic Profile. The table listed below represents the Input Assembly data.
PAGE 304
Chapter 8 EtherNet/IP Communications Bit INT DINT 15 14 13 12 11 10 9 8 7 6 36 37 18 TotalRealPower 19 TotalReactivePwr 20 TotalApparentPwr 21 TotalPowerFactor 22 Datalink0 23 Datalink1 24 Datalink2 25 Datalink3 26 Datalink4 27 Datalink5 28 Datalink6 29 Datalink7 38 39 40 41 42 43 44 45 46 47 48 49 50 51 52 53 54 55 56 57 58 59 60 61 30 62 63 31 64 65 32 66 67 33 68 69 34 70 71 35 72 73 36 74 75 37 76 77 304 38 Rockwell Automation Publication 193-UM0
PAGE 305
EtherNet/IP Communications Chapter 8 For example, E300_Overload:I.Data[12] represents L1 Current as shown below. 6. To control the output relays or remotely reset the E300 Electronic Overload Relay, navigate to the output tags created by the Generic Profile. The table listed below represents the Input Assembly data.
PAGE 306
Chapter 8 EtherNet/IP Communications For example, E300_Overload:O.Data[0].0 represents Relay Output Pt00 as shown below. E-mail/Text The E300 Electronic Overload Relay EtherNet/IP Communication Module is capable of sending e-mail messages and text notifications for different trip and warning events using an Simple Mail Transfer Protocol (SMTP) server.
PAGE 307
EtherNet/IP Communications Chapter 8 E-mail Configuration To be able to send an e-mail, the IP address of the hostname of a Simple Mail Transfer Protocol (SMTP) server must be configured and notifications must be selected. Follow these steps to configure an e-mail notification. 1. In the web browser, enter the IP address of the E300 Electronic Overload Relay EtherNet/IP Communication Module URL of the web browser. 2. Select Administrative Settings>Device Identity 3.
PAGE 308
Chapter 8 EtherNet/IP Communications 5. Type the information into the e-mail notification fields as stated below. Multiple e-mail addresses can be entered into the E-mail Recipient field by separating each e-mail address with a semicolon (;). The E-mail Recipient field is limited to 255 characters. E-mail Recipient E-Mail Sender SMTP Server SMTP Username SMTP Password SMTP Port The e-mail address of the person who will receive the notifications.
PAGE 309
EtherNet/IP Communications Chapter 8 Text Notifications The E300 Electronic Overload Relay EtherNet/IP Communication Module can send a text message to a wireless phone by e-mailing the wireless phone's service provider. The format for the text message is provided by the service provider and looks similar to the example formats below. • AT&T™: 10-digit wireless phone number@txt.att.net • Sprint®: 10-digit wireless phone number@messaging.sprint.pcs.
PAGE 310
Chapter 8 EtherNet/IP Communications Status LED Module Status Link1 or Link2 310 Color State None — Green, Red, Not Illuminated Flashing (once) Green Flashing Green Solid Red Flashing Red Solid None — Green Flashing Green Solid Possible Cause Corrective Action Check the control power connection on the A1 The E300 EtherNet/IP Communication Module is and A2 terminals of the E300 EtherNet/IP not receiving power. Control Module. Normal This is a normal power-up sequence.
PAGE 311
Chapter 9 Firmware Updates Introduction The purpose of this chapter is to provide detailed information regarding firmware compatibility among the various E300 Electronic Overload Relay modules and to provide instructions on how to upgrade firmware for an E300 Electronic Overload Relay module. Firmware Compatibility The sensing, control, and communication modules of an E300 Electronic Overload Relay have their own firmware for the functionality of the module and its subsystems.
PAGE 312
Chapter 9 Firmware Updates Upgrading Firmware Firmware for the E300 Electronic Overload Relay modules and their associated subsystems can be downloaded from the Product Compatibility and Download Center located at http://www.rockwellautomation.com/rockwellautomation/ support/pcdc.page?. After the firmware has been downloaded and installed, run the ControlFLASH application by selecting ControlFLASH from the Start menu located at Start -> FLASH Programming Tools -> ControlFlash as shown below.
PAGE 313
Firmware Updates Chapter 9 Select the module upgrade file and press Next.
PAGE 314
Chapter 9 Firmware Updates Select the specific device to upgrade and press OK. Select the specific module subsystem to upgrade and press OK.
PAGE 315
Firmware Updates Chapter 9 Select the specific firmware revision for the firmware upgrade and press Next. Verify that you want to upgrade the firmware for that specific module subsystem by pressing Yes.
PAGE 316
Chapter 9 Firmware Updates The ControlFLASH utility will begin to download the new firmware files. At the end of the download, the device will automatically reset. When the device finishes its power cycle sequence, a successful firmware upgrade message will be displayed. Press OK to finish the firmware upgrade process. IMPORTANT 316 Do not interrupt power or communications to the device during the firmware upgrade process. Failure of control power or communications could permanently damage the device.
PAGE 317
Chapter 10 Troubleshooting Introduction The purpose of this chapter is to assist in troubleshooting the E300 Electronic Overload Relay using its advisory LEDs and diagnostic parameters. ATTENTION: Servicing energized industrial control equipment can be hazardous. Electrical shock, burns, or unintentional actuation of controlled industrial equipment may cause death or serious injury.
PAGE 318
Chapter 10 Troubleshooting Trip/Warn LED The E300 Electronic Overload Relay Power LED identifies the reason for the trip or warning event. The E300 Electronic Overload Relay will display a long and short blinking pattern to identify the reason for the trip or warning event. Table 341 - Trip / Warn LED Blinking Red Blinking Yellow Trip Event Warning Event Listed below are the blink patterns for the E300 Electronic Overload Relay trip and warning events.
PAGE 319
Troubleshooting Control Power Code Long Blink Pattern Chapter 10 Short Blink Pattern Under kW 2 1 Over kW 2 2 Under kVAR Consumed 2 3 Over kVAR Consumed 2 4 Under kVAR Generated 2 5 Over kVAR Generated 2 6 Under kVA 2 7 Over kVA 2 8 Under PF Lagging 2 9 Over PF Lagging 2 10 Under PF Leading 2 11 Over PF Leading 2 12 Test 3 1 PTC 3 2 DeviceLogix 3 3 Operator Station 3 4 Remote Trip 3 5 Blocked Start 3 6 Hardware Fault 3 7 Configuration 3 8 Op
PAGE 320
Chapter 10 Troubleshooting • Setting Overload Reset Mode (Parameter 173) to “Automatic” to allow the unit to automatically reset after an overload trip • Setting Trip Reset (Parameter 163) to a value of 1, “Trip Reset” IMPORTANT Trip/Warn LED Troubleshooting Procedures An overload trip cannot be reset until the value of Percent Thermal Capacity Utilized (Parameter 1) is below the value set in Overload Reset Level (Parameter 174). Trip Description Possible Cause Test Trip 1.
PAGE 321
Troubleshooting Chapter 10 Trip Description Possible Cause Corrective Action 1. Firmware Downgrade corrupted: Non-volatile 1.Execute the Clear Command to the operating Non-Volatile Storage memory Statistics, History Logs, and % TCU Fault 2. Internal product failure 2. Consult the factory. 1. Verify firmware revisions of control module and sensing module 1. Firmware of sensing module is not compatible with control module firmware 2. Upgrade firmware of control module to v2.0 or higher Hardware Fault 3.
PAGE 322
Chapter 10 322 Troubleshooting Rockwell Automation Publication 193-UM015B-EN-P - June 2014
PAGE 323
Appendix A Specifications Electrical Specifications Table 343 - Motor/Load Ratings Terminals Rated Insulation Voltage (Ui) Rated Operating Voltage (Ue) IEC: UL: Rated Impulse Voltage (Uimp) Rated Operating Current (Ie) Rated Frequency Short Circuit Ratings Number of Poles Application 1/L1, 3/L2, 5/L3, 2/T1, 4/T2, 6/T3 690V AC 690V AC 600V AC 6 kV See Catalog Number Explanation 45...
PAGE 324
Appendix A Specifications Table 345 - Output Relay Ratings (Control Module and Expansion Digital Module) Utilization Category Resistive Load Rating (p.f. = 1.0) Inductive Load Rating (L/R = 7 ms) Short Circuit Current Rating (p.f. = 0.
PAGE 325
Specifications Appendix A Table 348 - Expansion Digital I/O Modules Expansion Digital I/O Modules 193-EXP-DIO-42-24D 193-EXP-DIO-42-120 193-EXP-DIO-42-240 Digital Output Rated Operational Voltage (Ue): 250V AC 250V AC 250V AC 2000Vrms for 1s 2000Vrms for 1s 2000Vrms for 1s Digital Output Rated Insulation Voltage (Ui): NA NA NA Rated Impulse Withstand Voltage (Uimp): Conditional Short Circuit Current: 1000 A 1000 A 1000 A Recommended Control Circuit Fuse: KTK-R (6 A, 600V) KTK-R (6 A, 600V) KTK-R (6 A, 600
PAGE 326
Appendix A Specifications Table 351 - Temperature Derating Control Module Voltage 120/240V AC Open Application 24V DC 120/240V AC Enclosed Application Electromagnetic Compatibility Specifications 24V DC Relay 0 Current Relay 1 Current Relay 2 Current 1.0 A 5.0 A 0.2 A 0.2 A 5.0 A 5.0 A 0.2 A 5.0 A 1.0 A 1.0 A 0.2 A 0.2 A 1.0 A 5.0 A 0.2 A 1.0 A 1.0 A 1.0 A 0.2 A 0.2 A 1.0 A 5.0 A 0.2 A 1.
PAGE 327
Specifications Appendix A Protection Table 353 - Protection Trip Yes Yes Yes Yes Yes Yes Yes Yes Yes Yes Yes Yes Yes Yes Yes Yes Yes Yes Yes Yes Yes Yes Yes Yes Yes Yes Yes Yes Yes Yes Yes Overload Phase Loss Ground Fault ➊ Stall Jam Underload Thermistor (PTC) Current Imbalance Communication Fault Communication Idle Remote Trip Blocked Start/Start Inhibit Under Voltage L-L Over Voltage L-L Voltage Unbalance Phase Rotation Under Frequency Over Frequency Under Real Power (kW) Over Real Power (kW) Under Re
PAGE 328
Appendix A Specifications Table 355 - Ground Fault Protection (External Ground Fault Module) Type Core Balanced Intended Use Equipment Protection Classification (Per UL 1053) Class I 20…100 mA 100…500 mA Protection Range 200 mA…1.0 A 1.0…5.0 A Accuracy Trip & Warning Time Delay 0.1…25.
PAGE 329
Specifications Appendix A Notes: Rockwell Automation Publication 193-UM015B-EN-P - June 2014 329
PAGE 330
Appendix A 330 Specifications Rockwell Automation Publication 193-UM015B-EN-P - June 2014
PAGE 331
Appendix B Parameter List This appendix lists all accessible parameters of the E300™ overload relay in numerical order. Overview The setting range for each parameter is provided to assist especially for applications where it is desirable to set values from a logic controller via a network connection. Information values provided include the following: Group Device Monitor Value Function Setting Range Indicated as raw numerical values.
PAGE 332
Appendix B Parameter List Param Parameter Name No.
PAGE 333
Parameter List Group Device Monitor (continued) Param Parameter Name No.
PAGE 334
Appendix B Group Device Monitor (continued) 334 Parameter List Param Parameter Name No.
PAGE 335
Parameter List Param Parameter Name No.
PAGE 336
Appendix B Parameter List Param Parameter Name No.
PAGE 337
Parameter List Param Parameter Name No.
PAGE 338
Appendix B Group Energy Monitoring (Continued) Analog Monitoring 338 Parameter List Param Parameter Name No.
PAGE 339
Parameter List Group Analog Monitoring (Continued) Param Parameter Name No.
PAGE 340
Appendix B Group Analog Monitoring (Continued) Trip/Warn History 340 Parameter List Param Parameter Name No.
PAGE 341
Parameter List Param Parameter Name No.
PAGE 342
Appendix B Parameter List Param Parameter Name No.
PAGE 343
Parameter List Param Parameter Name No.
PAGE 344
Appendix B Group Command (Continued) Overload Setup Device Setup 344 Parameter List Param Parameter Name No.
PAGE 345
Parameter List Group Device Setup (continued) Param Parameter Name No.
PAGE 346
Appendix B Group Device Setup (continued ) 346 Parameter List Param Parameter Name No.
PAGE 347
Parameter List Group Device Setup (continued Param Parameter Name No.
PAGE 348
Appendix B Group Device Setup (continued 348 Parameter List Param Parameter Name No.
PAGE 349
Parameter List Group Device Setup (continued Options Setup Param Parameter Name No.
PAGE 350
Appendix B Group Options Setup (Continued) 350 Parameter List Param Parameter Name No.
PAGE 351
Parameter List Group Current Setup Param Parameter Name No.
PAGE 352
Appendix B Parameter List Param No.
PAGE 353
Parameter List Group Output Setup Continued Param Parameter Name No.
PAGE 354
Appendix B Group Output Setup (Continued) DeviceLogix Setup 354 Parameter List Param Parameter Name No.
PAGE 355
Parameter List Group DeviceLogix Setup (Continued) Voltage Setup Power Setup Param Parameter Name No.
PAGE 356
Appendix B Group Power Setup (Continued) 356 Parameter List Param Parameter Name No.
PAGE 357
Parameter List Group Power Setup (Continued) Diagnostic Display Setup Param Parameter Name No.
PAGE 358
Appendix B Group Diagnostic Display Setup (Continued) Analog1 Setup 358 Parameter List Param Parameter Name No.
PAGE 359
Parameter List Group Analog1 Setup (Continued) Param Parameter Name No.
PAGE 360
Appendix B Parameter List Param Parameter Name No.
PAGE 361
Parameter List Group Analog1 Setup (continued) Analog2 Setup Param Parameter Name No.
PAGE 362
Appendix B Parameter List Param Parameter Name No.
PAGE 363
Parameter List Group Analog2 Setup (continued) Param Parameter Name No.
PAGE 364
Appendix B Group Analog2 Setup (continued) Analog3 Setup 364 Parameter List Param Parameter Name No.
PAGE 365
Parameter List Group Analog3 Setup (Continued) Param Parameter Name No.
PAGE 366
Appendix B Group Analog3 Setup (continued) 366 Parameter List Param Parameter Name No.
PAGE 367
Parameter List Group Analog3 Setup (continued) Analog4 Setup Param Parameter Name No.
PAGE 368
Appendix B Group Analog4 Setup (continued) 368 Parameter List Param Parameter Name No.
PAGE 369
Parameter List Group Analog4 Setup (continued) Param Parameter Name No.
PAGE 370
Appendix B Group Analog4 Setup (continued) 370 Parameter List Param Parameter Name No.
PAGE 371
Appendix C EtherNet/IP Information Common Industrial Protocol (CIP) Objects The E300 Electronic Overload Relay’s EtherNet/IP Communication Module supports the following Common Industrial Protocol (CIP).
PAGE 372
Appendix C EtherNet/IP Information Identity Object — CLASS CODE 0x0001 The following three instances of the Identity Object are supported: Table 358 - Identity Object Instances Instance 1 2 3 Name Operating System Flash Boot code Flash Sensing Module Revision Attribute The firmware rev of the Control firmware stored in flash memory The firmware rev of the Boot Code stored in flash memory The firmware rev of the Sensing Module firmware The following class attributes are supported for the Identity Object
PAGE 373
EtherNet/IP Information Appendix C Table 361 - Extended Device Status Field (bits 4-7) in “Status” Instance Attribute 5 Value 0 1 2 3 4 5 6 7 Description Self-Testing or Unknown Firmware Update in Progress At least one faulted I/O connection No I/O connections established Non-Volatile Configuration bad Major Fault – either bit 10 or bit 11 is true (1) At least one I/O connection in run mode At least one I/O connection established, all in idle mode Instance 2 of the Identity Object contains the following
PAGE 374
Appendix C EtherNet/IP Information Instance 3 of the Identity Object contains the following attributes: Table 363 - Identity Object Instance 3 Attributes Attribute ID Access Rule Name Data Type 1 Get Vendor UINT 2 3 Get Get 4 Get Device Type Product Code Revision Major Revision Minor Revision UINT UINT Structure of: USINT USINT 5 Get Status WORD 6 Get 7 Get 8 Get Serial Number Product Name String Length ASCII String State UDINT Structure of: USINT STRING USINT 9 Get Configurati
PAGE 375
EtherNet/IP Information Appendix C Table 365 - Assembly Object Class Attributes Attribute ID Access Rule Name Data Type Value 2 Get Max. Instance UINT 199 The following static assembly instance attributes are supported for each assembly instance.
PAGE 376
Appendix C EtherNet/IP Information Table 369 - Instance 2 — Basic Overload Output Assembly from ODVA Profile Byte 0 Bit 7 Bit 6 Bit 5 Bit 4 Bit 3 Bit 2 Bit 1 Fault Reset Bit 0 Table 370 - Instance 2 Attributes Attribute ID Access Rule Member Index Name 1 Get Number of Members in Member List Member List Member Data Description 0 Member Path Size 2 Get Member Path Member Data Description 1 Member Path Size Member Path 3 Set Data 4 Get Size 100 Get Name Data Type UINT Array of STRUCT UINT UINT Packe
PAGE 377
EtherNet/IP Information INT 2 3 4 5 DINT 15 14 13 12 11 10 9 8 4 3 2 1 0 Size (bits) Param 32 171 2 FLA2Setting 32 177 8 1 1 1 1 1 1 2 8 8 16 16 16 16 16 16 16 16 16 16 16 16 16 16 16 16 16 16 16 16 16 8 8 4 3 3 3 3 2 2 2 2 8 172 173 176 247 248 364 377 1101 174 175 183 189 184 190 185 191 186 192 187 193 139 145 140 146 141 147 142 148 143 149 233 221 222 224 225 226 227 228 229 230 231 232 NA X 6 X 3 X X X X 7 4 5 6 7 8 9 10 11 12 13 TripClass OLPTCResetMode SingleOrThreePh G
PAGE 378
Appendix C EtherNet/IP Information INT DINT 15 14 13 12 11 10 9 8 7 6 5 4 3 2 Language 1 OutAAssignment 32 OuBAssignment 16 OutCAssignment InPt00Assignment InPt01Assignment 33 InPt02Assignment InPt03Assignment InPt04Assignment InPt05Assignment 34 17 X 18 19 20 21 43 22 23 47 25 26 JamInhibitTime JamTripDelay JamTripLevel JamWarningLevel ULTripDelay ULTripLevel ULWarningLevel CIInhibitTime 54 27 55 28 CITripDelay CITripLevel CIWarningLevel CTPrimary CTSecondary UCInhibitTime 5
PAGE 379
EtherNet/IP Information INT DINT 15 60 30 61 13 12 11 10 9 8 7 6 5 L2UCTripDelay 4 L2UCTripLevel L2UCWarningLevel L3UCTripDelay L3UCTripLevel 62 31 63 L3UCWarningLevel OCInhibitTime L1OCTripDelay L1OCTripLevel 64 32 65 L1OCWarningLevel L2OCTripDelay L2OCTripLevel L2OCWarningLevel 66 33 67 L3OCTripDelay L3OCTripLevel L3OCWarningLevel LineLossInhTime 68 34 69 70 71 72 73 74 75 76 77 14 35 36 37 38 L1LossTripDelay L2LossTripDelay L3LossTripDelay Datalink0 Datalink1 Datalink2 Datalink3 Dat
PAGE 380
Appendix C EtherNet/IP Information INT 78 DINT 15 14 13 OutPt00PrFltAct OutPt00PrFltVal OutPt00ComFltAct OutPt00ComFltVal OutPt00ComIdlAct OutPt00ComIdlVal OutPt01PrFltAct OutPt01PrFltVal 12 11 10 9 8 X X X OutPt02ComIdlAct OutPt02ComIdlVal OutDig1PrFltAct OutDig1PrFltVal OutDig1ComFltAct OutDig1ComFltVal OutDig1ComIdlAct OutDig1ComIdlVal 0 X X X OutPt01ComFltAct OutPt01ComFltVal OutPt01ComIdlAct OutPt01ComIdlVal OutPt02PrFltAct OutPt02PrFltVal OutPt02ComFltAct OutPt02ComFltVal X X X X X X X X
PAGE 381
EtherNet/IP Information INT DINT 15 OWTripDelay Size (bits) 8 8 8 8 16 16 8 8 16 16 8 8 8 8 8 8 8 8 8 8 8 8 8 8 8 8 8 8 Param 352 363 355 356 357 358 359 360 361 362 365 366 367 368 369 370 371 372 373 374 375 376 426 427 378 379 382 383 50 UWTripLevel 32 380 51 UWWarningLevel 32 381 52 OWTripLevel 32 384 53 OWWarningLevel 32 385 OVARCTripDelay 8 8 8 8 386 387 390 391 55 UVARCTripLevel 32 388 56 UVARCWarnLevel 32 389 57 OVARCTripLevel 32 392 58 OVARCWarnLevel 32 393
PAGE 382
Appendix C EtherNet/IP Information INT DINT 15 OVARGTripDelay Size (bits) 8 8 8 8 Param 394 395 398 399 60 UVARGTripLevel 32 396 61 UVARGWarnLevel 32 397 62 OVARGTripLevel 32 400 63 OVARGWarnLevel 32 401 OVATripDelay 8 8 8 8 402 403 406 407 65 UVATripLevel 32 404 66 UVAWarningLevel 32 405 67 OVATripLevel 32 408 68 OVAWarningLevel 32 409 8 8 8 8 8 8 8 8 8 8 8 8 8 8 8 8 16 16 16 16 16 16 16 16 16 16 410 411 412 413 414 415 416 417 418 419 420 421 422 423 424 425 428
PAGE 383
EtherNet/IP Information INT DINT 15 156 78 157 158 159 160 161 162 163 79 80 81 14 13 12 11 10 9 8 7 6 5 InAMod1C0TripDly 4 3 2 1 0 X X InAMod1C1TripDly InAMod1C2TripDly Reserved InAMod1C0TripLvl InAMod1C0WarnLvl InAMod1C1TripLvl InAMod1C1WarnLvl InAMod1C2TripLvl InAMod1C2WarnLvl InAnMod1Ch00Type InAnMod1Ch01Type 164 82 X InAnMod1Ch02Type Reserved X 165 X X X X InAMod1Ch1Format InAMod1C1FiltFrq InAMod1C1OpCktSt 166 83 167 X 168 84 169 170 171 172 173 174 175 85 86 87 X X Ou
PAGE 384
Appendix C EtherNet/IP Information INT DINT 15 14 13 12 11 10 9 7 6 5 4 3 2 1 InAnMod2Ch00Type 88 X InAnMod2Ch02Type Reserved X 177 X X X X InAMod2Ch1Format InAMod2C1FiltFrq InAMod2C1OpCktSt 178 89 179 X X X X X 90 181 91 92 93 X X X X InAMod2C0TmpUnit InAnMod2Ch0RTDEn InAMod2C1TmpUnit InAnMod2Ch1RTDEn InAMod2C2TmpUnit InAnMod2Ch2RTDEn OutAnMod2FltActn X OutAnMod2Select InAMod2Ch0Format InAMod2C0FiltFrq InAMod2C0OpCktSt X X X X X X X X X X X X X X OutAnMod2dlActn OutA
PAGE 385
EtherNet/IP Information INT 190 DINT 15 14 13 12 InAMod3Ch1Format InAMod3C1FiltFrq InAMod3C1OpCktSt 11 10 X 95 191 X X X X InAMod3C0TmpUnit InAnMod3Ch0RTDEn InAMod3C1TmpUnit InAnMod3Ch1RTDEn InAMod3C2TmpUnit InAnMod3Ch2RTDEn OutAnMod3FltActn 9 X X 192 96 193 194 195 196 197 198 199 97 98 99 X X X 7 6 5 4 3 X X X 2 X 1 X 0 X X X InAMod3Ch2Format InAMod3C2FiltFrq InAMod3C2OpCktSt X X X X X X X X 8 X X X X X X OutAnMod3dlActn OutAnMod3Type Reserved InAMod4C0TripDly InAMod4C
PAGE 386
Appendix C EtherNet/IP Information Instance 120 - Configuration Assembly Revision 1 The following table shows Attribute 3 Format and Attribute 2 Member List for revision 1 of the assembly. This is a stripped down simple version of a config assembly.
PAGE 387
EtherNet/IP Information INT 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 33 34 35 36 37 38 39 40 41 42 43 44 45 46 47 48 49 50 51 DINT 15 14 13 InputStatus0 2 InputStatus1 OutputStatus 3 OpStationStatus TripStsCurrent 4 WarnStsCurrent TripStsVoltage 5 WarnStsVoltage TripStsPower 6 WarnStsPower TripStsControl 7 WarnStsControl TripStsAnalog 8 WarnStsAnalog Reserved 9 MismatchStatus 12 11 10 9 8 7 6 5 4 3 10 CurrentImbal AvgPercentFLA Size (bits) 16 16 16 16 1
PAGE 388
Appendix C EtherNet/IP Information INT 52 53 54 55 56 57 58 59 60 61 62 63 64 65 DINT 15 14 13 InAnMod1Ch02 26 Reserved InAnMod2Ch00 27 InAnMod2Ch01 InAnMod2Ch02 28 Reserved InAnMod3Ch00 29 InAnMod3Ch01 InAnMod3Ch02 30 Reserved InAnMod4Ch00 31 InAnMod4Ch01 InAnMod4Ch02 32 Reserved 12 11 10 9 8 7 6 5 4 3 2 1 0 Size (bits) 16 16 16 16 16 16 16 16 16 16 16 16 16 16 Param 113 1103 114 115 116 1103 117 118 119 1103 120 121 122 1103 Instance 199 - All Diagnostics Produced Assembly Table 377 - I
PAGE 389
EtherNet/IP Information INT 28 29 30 31 32 33 34 35 36 37 38 39 40 41 42 43 44 45 46 47 48 49 50 51 52 53 54 55 56 57 58 59 60 61 62 63 64 65 66 67 68 69 70 71 72 73 74 75 76 77 DINT 15 14 14 13 12 11 10 9 8 7 6 5 4 3 2 1 0 Appendix C Size (bits) Param L3Current 32 45 GFCurrent Reserved AvgVoltageLtoL L1toL2Voltage L2toL3Voltage L3toL1Voltage 16 16 16 16 16 16 51 1103 56 53 54 55 18 TotalRealPower 32 67 19 TotalReactivePwr 32 71 20 TotalApparentPwr 32 75 21 TotalPowerF
PAGE 390
Appendix C EtherNet/IP Information Connection Object — CLASS CODE 0x0005 No class attributes are supported for the Connection Object Multiple instances of the Connection Object are supported, instances 1, 2 and 4 from the group 2 predefined master/slave connection set, and instances 5-7 are available explicit UCMM connections. Instance 1 is the Predefined Group 2 Connection Set Explicit Message Connection.
PAGE 391
EtherNet/IP Information Appendix C Instance 2 is the Predefined Group 2 Connection Set Polled IO Message Connection.
PAGE 392
Appendix C EtherNet/IP Information Instance 4 is the Predefined Group 2 Connection Set Change of State / Cyclic I/ O Message Connection.
PAGE 393
EtherNet/IP Information Appendix C Instances 5 - 7 are available group 3 explicit message connections that are allocated through the UCMM.
PAGE 394
Appendix C EtherNet/IP Information 22 instances of the Discrete Input Point Object are supported.
PAGE 395
EtherNet/IP Information Appendix C Table 387 - Discrete Output Point Object Class Attributes Attribute ID Access Rule Name Data Type Value 1 Get Revision UINT 1 2 Get Max. Instance UINT 11 11 instances of the Discrete Output Point Object are supported.
PAGE 396
Appendix C EtherNet/IP Information The following common services are implemented for the Discrete Output Point Object.
PAGE 397
EtherNet/IP Information Appendix C The following common services are implemented for the Analog Input Point Object. Table 394 - Analog Input Point Object Common Services Implemented for: Class Instance Yes Yes No Yes Service Code 0x0E 0x10 Service Name Get_Attribute_Single Set_Attribute_Single Analog Output Point Object — CLASS CODE 0x000B Table 395 - Analog Output Point Object Class Attributes Attribute ID Access Rule Name Data Type Value 1 Get Revision UINT 2 2 Get Max.
PAGE 398
Appendix C EtherNet/IP Information The following common services are implemented for the Analog Output Point Object.
PAGE 399
EtherNet/IP Information Appendix C The following common services are implemented for the Parameter Object.
PAGE 400
Appendix C EtherNet/IP Information Table 405 - Discrete Output Group Object Instance 1 Attributes Attribute ID 3 4 6 Access Rule Get Get Get/Set Name Number of Instances Binding Command Data Type USINT Array of UINT BOOL 104 Get/Set Network Status Override BOOL 105 Get/Set Comm Status Override BOOL Value 11 1,2,3,4,5,6,7,8,9,10,11 0=idle; 1=run 0=No Override (go to safe state) 1=Override (run local logic) 0=No override (go to safe state) 1=Override (run local logic) Instances 2-5 each represen
PAGE 401
EtherNet/IP Information Appendix C Table 408 - Control Supervisor Object Instance 1 Attributes Attribute ID Access Rule Name Data Type 10 Get Tripped BOOL 11 Get Warning BOOL 12 Get/Set Fault Reset BOOL Value 0 = No Fault present 1 = Fault Latched 0 = No Warning present 1 = Warning present (not latched) 0->1 = Trip Reset otherwise no action The following common services are implemented for the Control Supervisor Object.
PAGE 402
Appendix C EtherNet/IP Information Table 412 - Base Energy Object Class Attributes Attribute ID 1 Access Rule Get Name Object Revision Data Type USINT Value 2 A single instance of the Base Energy Object is supported Table 413 - Base Energy Instance Attributes Attribute ID Access Rule 1 Get 2 Get Name Data Type Energy/Resource Type UINT Energy Object WORD Capabilities 3 Get Energy Accuracy UINT 4 Get UINT 5 Get Real x.xxx kW (TBD) 7 Get ODOMETER Returns params 80-84 values.
PAGE 403
EtherNet/IP Information Attribute ID 11 Name Value Energy Transfer Rate User Setting 0.
PAGE 404
Appendix C EtherNet/IP Information Attribute ID Access Rule 23 Get 24 25 26 27 28 29 30 31 32 33 34 35 36 37 38 Get Get Get Get Get Get Get Get Get Get Get Get Get Get Get 39 Get 40 Get Name Percent Voltage Unbalance L1 Real Power L2 Real Power L3 Real Power Total Real Power L1 Reactive Power L2 Reactive Power L3 Reactive Power Total Reactive Power L1 Apparent Power L2 Apparent Power L3 Apparent Power Total Apparent Power L1 True Power Factor L2 True Power Factor L3 True Power Factor Three Phase T
PAGE 405
EtherNet/IP Information Attribute ID 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 33 34 35 36 37 38 39 40 41 Data Type REAL REAL REAL REAL REAL REAL REAL REAL REAL REAL REAL REAL REAL REAL REAL REAL REAL REAL REAL REAL REAL REAL REAL REAL REAL UINT STRUCT of UINT Padded EPATH Name L1 to N Voltage L2 to N Voltage L3 to N Voltage Avg Voltage L to N L1 to L2 Voltage L2 to L3 Voltage L3 to L1 Voltage Avg Voltage Lto N Percent Voltage Unbalance L1 Real Power L2 Real Power L3 Real Power Total Real Pow
PAGE 406
Appendix C EtherNet/IP Information Attribute ID Access Rule Name Data Type 5 Set / SSV Date and Time  (Local Time) DINT[7] – Array of seven DINTs 6 Set / SSV Current UT value (UTC Time) LINT 7 Set / SSV UTC Date and Time (UTC Time) DINT[7] – Array of seven DINTs 8 Set / SSV Time Zone String Struct of UDINT SINT[Length] 9 Set / SSV DST Adjustment INT 10 Set / SSV Enable DST USINT 11 Set Current value (local time) LINT Value Current adjusted time in human readable format.
PAGE 407
EtherNet/IP Information Appendix C Table 422 - DPI Fault Object Class Attributes Attribute ID 1 2 Access Rule Get Get 3 Get/Set 4 Get 5 Get 6 Get Name Class Revision Number of Instances Data Type Value UINT 1 UINT 8 0=NOP; 1=Clear Fault; 2=Clear Flt Fault Cmd Write USINT Queue The instance of the Fault Queue Entry Fault Instance Read UINT containing information about the Fault that tripped the Device Fault Data list Struct of: The total number of parameters Number of Parameter Instances UINT in
PAGE 408
Appendix C EtherNet/IP Information The table below lists Fault Codes, Fault Text, and Fault Help Strings.
PAGE 409
EtherNet/IP Information Fault Code 47 48 49 50 51 52 53 54 55 56 57 58 59 60 61 62 63 64 65 66 67 68 69 70 71 72 73 74 75 76 77 78 79 80 81 82 83 84 85 86 87 88 89 90 91 92 93 94 95 96 Fault Text Fault47 Fault48 TestTrip PTCTrip DLXTrip OperStationTrip RemoteTrip BlockedStartTrip Trip55 ConfigTrip Trip57 DLXFBTimeoutTrip Trip59 Trip60 Trip61 NVSTrip Trip63 Trip64 InAnMod1Ch00Trip InAnMod1Ch01Trip InAnMod1Ch02Trip InAnMod2Ch00Trip InAnMod2Ch01Trip InAnMod2Ch02Trip InAnMod3Ch00Trip InAnMod3Ch01Trip InAnMod3
PAGE 410
Appendix C EtherNet/IP Information Fault Code 97 98 99 Fault Text Trip97 HardwareFltTrip Trip99 Help Text A hardware fault condition was detected DPI Warning Object — CLASS CODE 0x0098 This object provides access to warning information within the device.
PAGE 411
EtherNet/IP Information Appendix C The following common services are implemented for the DPI Warning Object. Table 428 - DPI Warning Object Common Services Service Code 0x0E 0x10 Implemented for: Class Instance Yes Yes Yes No Service Name Get_Attribute_Single Set_Attribute_Single The table below lists Warning Codes, Warning Text, and Warning Help Strings.
PAGE 412
Appendix C EtherNet/IP Information Warning Code 38 39 40 41 42 43 44 45 46 47 48 49 50 51 52 53 54 55 56 57 58 59 60 61 62 63 64 65 66 67 68 69 70 71 72 73 74 75 76 77 78 79 80 81 82 83 84 85 86 412 Warning Text Warning Help Text OverKVARGenWarn Under Power kVA Over Power kVA Under PF Lagging Over PF Lagging Under PF Leading Over PF Leading Warning 45 Warning 46 Warning 47 Warning 48 Warning49 PTC DLXWarning Warning52 Warning53 Warning54 Warning55 ConfigWarning Warning57 DLXFBTimeoutWarn Warning59 PM
PAGE 413
EtherNet/IP Information Warning Code 87 88 89 90 91 92 93 94 95 96 97 98 99 Warning Text Warning Help Text AnalogMod3Warn AnalogMod4Warn Warning89 CtlModMismatch SenseModMismatch CommModMismatch OperStatMismatch DigModMismatch AnModMismatch Warning96 Warning97 HardwareFltWarn Warning99 Analog Expansion Module 3 is not operating properly Analog Expansion Module 4 is not operating properly Appendix C Control Module installed does not match the expected type Sensing Module installed does not match the e
PAGE 414
Appendix C EtherNet/IP Information Comm Adapter Info Object — CLASS CODE 0x0C8 No class attributes are supported.
PAGE 415
EtherNet/IP Information Attribute 2 3 4 5 6 Name Trip and Warning Status Digital I/O Status Device Data and Status Config Trip/Warning Data Motor Statistics Byte 0 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 0 1 2 3 4 5 0 1 2 3 4 5 6 7 8 9 0 1 2 3 0 1 2 3 4 5 6 7 Appendix C Data Trip Status Current Trip Status Voltage Trip Status Power Trip Status Control Trip Status Analog Warning Status Current Warning Status Voltage Warning Status Power Warning Status Control Warning Status Analog Inpu
PAGE 416
Appendix C EtherNet/IP Information Attribute 7 8 9 10 416 Name Time and Data Current and GF Current in Amps Current as a Percentage of FLA Line to Line Voltage Byte 0 1 2 3 4 5 6 7 8 9 10 11 0 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 0 1 2 3 4 5 6 7 0 1 2 3 4 5 6 7 Data Year Month Day Hour Minute Second L1 Current L2 Current L3 Current Average Current Ground Fault Current Current Imbalance L1 Percent FLA L2 Percent FLA L3 Percent FLA Average Percent FLA L1-L2 Voltage L2-L3 Voltage
PAGE 417
EtherNet/IP Information Attribute 11 12 13 14 Name Line to Neutral Voltage Voltage Data Real Power Reactive Power Byte 0 1 2 3 4 5 6 7 0 1 2 3 4 5 0 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 0 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 Appendix C Data L1-N Voltage L2-N Voltage L3-N Voltage Average Voltage L-N Voltage Unbalance L-L Voltage Frequency Voltage Phase Rotation L1 Real Power L2 Real Power L3 Real Power Average Real Power L1 Reactive Power L2 Reactive Power L3 Reactive Power Average Real Po
PAGE 418
Appendix C EtherNet/IP Information Attribute 15 16 17 418 Name Apparent Power Power Factor Real Energy Byte 0 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 0 1 2 3 4 5 6 7 0 1 2 3 4 5 6 7 8 9 Data L1 Apparent Power L2 Apparent Power L3 Apparent Power Average Apparent Power L1 Power Factor L2 Power Factor L3 Power Factor Total Power Factor kWh X 10E9 kWh X 10E6 Total Real Energy Rockwell Automation Publication 193-UM015B-EN-P - June 2014 kWh X 10E3 kWh kWh X 10E -3
PAGE 419
EtherNet/IP Information Attribute 18 19 20 Name Reactive Energy Total Apparent Energy Demand Byte 0 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 0 1 2 3 4 5 6 7 8 9 0 1 2 3 4 5 Appendix C Data kVARh X 10E9 kVARh X 10E6 Total Reactive Energy Consumed kVARh X 10E3 kVARh kVARh X 10E-3 kVARh X 10E9 kVARh X 10E6 Total Reactive Energy Generated kVARh X 10E3 kVARh kVARh X 10E-3 kVARh X 10E9 kVARh X 10E6 Total Reactive Energy Net kVARh X 10E3 kVARh kVARh X 10E-3 kVAh
PAGE 420
Appendix C EtherNet/IP Information Attribute 21 22 23 24 25 420 Name Peak Demand Analog Input Values Analog Expansion Module Status Trip History Warning History Byte 0 1 2 3 4 5 0 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 0 1 2 3 4 5 6 7 0 1 2 3 4 5 6 7 8 9 0 1 Data Max kW Demand Max VAR Demand Max VA Demand Analog Expansion Module 1 Input Channel 00 Analog Expansion Module 1 Input Channel 01 Analog Expansion Module 1 Input Channel 02 Analog Expansion Module 2 Input Channel
PAGE 421
EtherNet/IP Information Attribute Name Byte 0 1 2 3 4 5 26 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 Trip Snapshot Appendix C Data TS L1 Current TS L2 Current TS L3 Current TS % TCU TS GF Current TS L1-L2 Voltage TS L2-L3 Voltage TS L3-L1 Voltage TS Total Real Power TS Total kVAR TS Total kVA TS Total PF The following common services are implemented.
PAGE 422
Appendix C 422 EtherNet/IP Information Rockwell Automation Publication 193-UM015B-EN-P - June 2014
PAGE 423
PAGE 424
Rockwell Automation Support Rockwell Automation provides technical information on the Web to assist you in using its products. At http://www.rockwellautomation.com/support you can find technical and application notes, sample code, and links to software service packs. You can also visit our Support Center at https://rockwellautomation.custhelp.com/ for software updates, support chats and forums, technical information, FAQs, and to sign up for product notification updates.