User Manual PowerMonitor 5000 Unit Catalog Numbers 1426
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.
Summary of Changes This manual contains new and updated information. Changes throughout this revision are marked by change bars, as shown to the right of this paragraph. New and Updated Information This table contains the changes made to this revision. Topic Page Added information about the M6 model. Throughout Added information on connecting to a ControlNet network. 40 Added information on setting up ControlNet network communication.
Summary of Changes For catalog number 1426-M5E (PN-54351) units manufactured from July 2012…January 2013, the accuracy is Class 0.5 not Class 0.2. All other characteristics and products are not impacted. The impacted units are those with manufacturing date codes of 0712, 0812, 0912, 1012, 1112, 1212, and 0113.
Table of Contents Preface Catalog Number Explanation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 9 Additional Resources . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 9 Chapter 1 PowerMonitor 5000 Unit Overview Safety . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Product Description. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
Table of Contents Power Frequency Variations (Category 7.0) . . . . . . . . . . . . . . . . . . . . . . . . IEEE 519 Pass/Fail Capability (M6 model) . . . . . . . . . . . . . . . . . . . . . . . . . IEEE 519 Pass/Fail Results . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . IEEE519_Overall_Status . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . IEEE-519 Short Term and Long Term Harmonic Results . . . . . . . . . . .
Table of Contents SCADA Applications . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 196 Controller Applications: Class 1 Connection. . . . . . . . . . . . . . . . . . . . . . 202 CIP Energy Object . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 216 Chapter 10 Maintenance Update the PowerMonitor 5000 Unit Firmware. . . . . . . . . . . . . . . . . . . 221 Upgrading the PowerMonitor 5000 Model and Communication . . .
Table of Contents Notes: 8 Rockwell Automation Publication 1426-UM001F-EN-P - November 2013
Preface Catalog Number Explanation 1426 -M5 Model Bulletin Number 1426 - PowerMonitor™ 5000 M5 - Base Power Monitor M6 - Basic Power Quality Monitor Additional Resources E -CNT Native Comms E - EtherNet/IP -A Optional Comms CNT - ControlNet Port DNT - DeviceNet Port [Blank] - No Optional Port Series A These documents contain additional information concerning related products from Rockwell Automation.
Preface Notes: 10 Rockwell Automation Publication 1426-UM001F-EN-P - November 2013
Chapter 1 PowerMonitor 5000 Unit Overview Safety ATTENTION: Only qualified personnel, following accepted safety procedures, can install, wire, and service the PowerMonitor 5000 unit and its associated components. Before beginning any work, disconnect all sources of power and verify that they are de-energized and locked out. Failure to follow these instructions can result in personal injury or death, property damage, or economic loss.
Chapter 1 PowerMonitor 5000 Unit Overview • Cost allocation – reporting actual energy cost by department or process to integrate energy information into management decisions • Billing and sub-billing – charging users of energy the actual usage cost rather than allocating by square footage or other arbitrary methods • Power system monitoring and control – display and control power flow and energy utilization • Demand management – monitoring power usage and controlling loads to reduce demand costs • Demand
PowerMonitor 5000 Unit Overview Chapter 1 Table 1 - Hardware Features Feature Description 1. Ethernet port – standard RJ45 jack with status indicators Ethernet port hardware is included on all models.
Chapter 1 PowerMonitor 5000 Unit Overview Functionality Table 2 - PowerMonitor 5000 Unit Functions Measured Parameters 1426-M5 1426-M6 Voltage, L-L and L-N • • Current, per phase and total • • Frequency, last cycle and average • • Voltage unbalance • • Current unbalance • • Real power, kW • • Symmetrical Component Analysis • • Reactive power, kVAR • • Apparent power, kVA • • True power factor, per phase and total • • Displacement power factor, per phase and total • • Re
PowerMonitor 5000 Unit Overview Chapter 1 Table 4 - Other Functions Function 1426-M5 1426-M6 Security • • Wiring diagnostics • • Wiring correction • • Network time synchronization • • Network demand synchronization • • Configuration lock • • IEEE 1588 Precision Time Protocol • • Waveform synchronization broadcast (WSB) • Relay (3) and KYZ (1) outputs • • Status inputs (4) • • Setpoint programming • • Sag and swell detection • • Logical setpoint programming • Web pag
Chapter 1 PowerMonitor 5000 Unit Overview Notes: 16 Rockwell Automation Publication 1426-UM001F-EN-P - November 2013
Chapter 2 Install the PowerMonitor 5000 Unit Only qualified personnel can install, wire, service, and maintain this equipment. Refer to and follow the safety guidelines and pay attention to all warnings and notices in these instructions. ATTENTION: Electrostatic discharge can damage integrated circuits or semiconductors. Follow these guidelines when you handle the module: • Touch a grounded object to discharge static potential. • Wear an approved wrist strap grounding device.
Chapter 2 Install the PowerMonitor 5000 Unit Use caution not to block the ventilation slots of the power monitor. All wiring, wire ways, enclosure components, and other obstructions must be a minimum of 50 mm (2.0 in.) from the top and bottom of the unit to provide ventilation and electrical isolation. Units can be mounted side-by-side. Note that access to the USB device port is required for initial configuration of the power monitor and can be required for eventual administration and maintenance.
Install the PowerMonitor 5000 Unit Chapter 2 3. Use M4 or #8 screws to mount the power monitor to your panel with 1.16 N•m (10 lb•in) of torque. 4. Ground the power monitor on a ground bus with a low-impedance earth ground connection. 5. Connect the ground bus to a functional earth ground on the panel. IMPORTANT Wire the PowerMonitor 5000 Unit The upper mounting slots are equipped with protective conductor terminals, that must make metal-to-metal contact with the grounded mounting panel.
Chapter 2 Install the PowerMonitor 5000 Unit Grounding This product is intended to be mounted to a well-grounded mounting surface, such as a metal panel. The upper mounting slots are equipped with protective conductor terminals, which must must make metal-to-metal contact with the mounting panel. In solid-state systems, grounding helps limit the effects of noise due to electromagnetic interference (EMI). Connect a 2.
Install the PowerMonitor 5000 Unit Chapter 2 Table 5 - Selecting Wiring Diagrams and Metering Modes Circuit Type Line - Line Voltage No. of CTs No.
Chapter 2 Install the PowerMonitor 5000 Unit The following wiring diagrams indicate typical voltage sensing connections to various types of power systems. Figure 3 - Diagram V1 - 3-phase, 4-wire Wye, (690V AC line-to-line maximum) Line L1 L2 L3 N Metering_Mode = Wye PowerMonitor 5000 Fuses (by user) V1 V2 V3 (1) VN VG Load (1) Fuse in neutral connection is required for impedance grounded systems.
Install the PowerMonitor 5000 Unit Chapter 2 Figure 5 - Diagram V3 - 3-phase, 4-wire Wye or Impedance Grounded Wye with PTs (no neutral PT) Line L1 L2 L3 Metering_Mode = Wye N PowerMonitor 5000 Fuses (by user) PTs (by user) V1 V2 V3 VN VG (1) Ground Load Ground (1) Fuse in neutral connection is required for impedance grounded systems.
Chapter 2 Install the PowerMonitor 5000 Unit Figure 7 - Diagram V5 -3-phase, 3-wire Grounded Wye with PTs Line L1 L2 L3 Metering_Mode = Wye Fuses (by user) PowerMonitor 5000 PTs (by user) V1 V2 V3 VN VG Ground Load Ground Ground Figure 8 - Diagram V6 - 3-phase, 3-wire Open Delta with Two PTs Line L1 L2 L3 Metering_Mode = Open Delta 2 CT or Open Delta 3 CT, as applicable Fuses (by user) PowerMonitor 5000 PTs (by user) V1 V2 V3 VN VG Ground Ground Load 24 Rockwell Automation Publication 142
Install the PowerMonitor 5000 Unit Chapter 2 Figure 9 - Diagram V7 - Split-phase (690V AC line-to-line maximum) Line L1 L2 L3 N Metering_Mode = Split-phase PowerMonitor 5000 Fuses (by user) V1 V2 V3 VN VG Load Ground Figure 10 - Diagram V8 - Split-phase with PTs Line L1 L2 N Metering_Mode = Split-phase PowerMonitor 5000 Fuses (by user) PTs (by user) V1 V2 V3 VN VG Ground Ground Load Rockwell Automation Publication 1426-UM001F-EN-P - November 2013 25
Chapter 2 Install the PowerMonitor 5000 Unit Figure 11 - Diagram V9 - 3-phase, 3-wire Grounded B-phase (690V AC line-to-line maximum) Metering_Mode = Delta Grd B Ph 2 CT Line or Delta Grd B Ph 3 CT, as applicable L1 L2 L3 PowerMonitor 5000 Fuses (by user) Distribution Ground V1 (1) V2 V3 VN VG Load Ground (1) You can also connect V2 to L2. In this case, omit the connection from V2 to VN.
Install the PowerMonitor 5000 Unit Chapter 2 Current Sensing Route the CT secondary wiring through the openings in the PowerMonitor 5000 unit as shown. I1 I2 I3 I4 X1 X2 To shorting terminal block and current transformer (CT). Use a shorting terminal block (included in the 1400-PM-ACC accessory kit), test block, or shorting switch (by user) for CT wiring to permit safely servicing connected equipment such as the PowerMonitor 5000 unit without deenergizing the power system. Use 2.5 mm2 (14 AWG) or 3.
Chapter 2 Install the PowerMonitor 5000 Unit Pay particular attention to the correct phasing and polarity of current sensing connections. The diagrams use the ‘dot’ convention to indicate transformer polarity. The dot indicates the H1 and X1 terminals on the primary and secondary of the CT respectively. Phasing of the CTs must correspond to the phasing of the voltage sensing connections. The following wiring diagrams indicate typical current sensing connections to various types of power systems.
Install the PowerMonitor 5000 Unit Chapter 2 Figure 15 - Diagram I3 - 3-phase, 3- or 4-wire, 3 CTs Metering_Mode = Wye, Delta 3 CT, Open Delta 3 CT, Delta Grd B Ph 3 CT, or Delta High-leg, as applicable Line L1 L2 N L3 (if used) Shorting Terminal Block (by user) PowerMonitor 5000 CTs (by user) CT1 I1 X1 CT2 I2 X1 CT3 I3 X1 CT4 (if used) Load I4 X1 Ground Status Inputs Up to four dry (non-powered) contacts can be connected to the PowerMonitor 5000 unit status inputs.
Chapter 2 Install the PowerMonitor 5000 Unit KYZ and Relay Outputs The KYZ solid-state relay output can be connected to an external pulse accumulator or controller. Relay outputs can be used for control of loads, switching of circuit breakers, signaling, and other applications. Wetting voltage must be provided by the external device or circuit. The KYZ output is designed for low-current switching. The diagram indicates typical KYZ and relay output wiring. Figure 17 - KYZ and Relay Outputs Z (N.C.
Install the PowerMonitor 5000 Unit Chapter 2 Control Power Connect the PowerMonitor 5000 unit to a source of 120/240V AC (or 24V DC, shown with dashed lines) control power through a user-provided disconnecting means, such as a switch or circuit breaker close to the power monitor. Provide overcurrent protection sized to protect the wiring, for example, a 5 A rated fuse. Overcurrent protection is included in the 1400-PM-ACC accessory kit. The PowerMonitor 5000 unit is internally protected.
Chapter 2 Install the PowerMonitor 5000 Unit Install Drivers You can download drivers from http://www.rockwellautomation.com/compatibility. Follow the steps listed below to install the USB driver. 1. Connect the PowerMonitor 5000 unit to your computer with a USB cable and apply power to the power monitor. The computer detects the new device and prompts you to install the driver. 2. Click ‘Yes, this time only’ and click Next. 3. Click Install from a list or specific location (Advanced) and click Next.
Install the PowerMonitor 5000 Unit Chapter 2 4. Click Browse and select the folder containing the driver .inf file. 5. Click Next. Wait while the driver installs. 6. Click Finish when the driver installation is complete.
Chapter 2 Install the PowerMonitor 5000 Unit Configure the Connection Follow these steps to configure the connection. 1. From the Windows desktop, choose Start > Settings > Network Connections. A new Local Area Connection with a Device Name ‘Remote NDIS based Device’ was added when you installed the driver. 2. Right-click the connection name and choose Properties. TIP 34 Setting up a PanelView 6 terminal in Windows CE follows a similar process.
Install the PowerMonitor 5000 Unit Chapter 2 3. Select Internet Protocol (TCP/IP) and click Properties. 4. Click Use the following IP address and type in the address 192.168.169.100. The default subnet mask 255.255.255.0 is correct. The default IP address of the PowerMonitor 5000 unit is 192.168.169.3.
Chapter 2 Install the PowerMonitor 5000 Unit Browse the PowerMonitor 5000 Web Page by Using the USB Connection Open the Internet Explorer browser on the computer and browse to the url http://192.168.169.3. The PowerMonitor 5000 web page displays in your browser. IMPORTANT Your browser must have Allow Scriptlets set to Enable for the applicable security zone for configuration changes to be made to the power monitor by using the web page.
Install the PowerMonitor 5000 Unit Chapter 2 Native Ethernet Communication The PowerMonitor 5000 unit connects easily to industry-standard Ethernet hubs and switches by using standard CAT-5 UTP (unshielded twisted-pair) cables with RJ45 connectors. The table below shows the cable and connector pin assignments. Table 6 - Cable and Connector Pin Assignments Terminal Signal Function 1 TX+ TX+ 2 TX- TX- 3 RX+ RX+ RX- RX- 4 5 6 7 8 Typical Ethernet connections are shown in the diagram below.
Chapter 2 Install the PowerMonitor 5000 Unit Optional DeviceNet Network Communication An optional DeviceNet port can be factory-installed in PowerMonitor 5000 units with a catalog number ending in -DNT, and can also be purchased from Rockwell Automation and installed by the user. ATTENTION: Power must be removed from the power monitor before inserting or removing an optional communication card. Inserting or removing an optional communication card under power can damage the card or the power monitor.
Install the PowerMonitor 5000 Unit Chapter 2 Figure 20 - Connecting a Powermonitor 5000 Unit to Other DeviceNet Devices USB Host Virtual Wiring Correction Power PowerMonitor 5000 Y ---- S1 K Rx O Rx com Rx C Internal 24VDC Sn Scom V- I1 Z V1 CAN_L EtherNet √IP S2 LNK ACT ---- S3 S4 ---- S com SHLD I2 V2 S com ---- K NS Y ---- Z R1 O L1 CAN_H V3 ---- R1 com DeviceNet 5 4 3 2 1 I3 L2 R1 C ---- R2 O R2 com GND V+ 1 2 3 4 5 Module status Network status USB Device Config
Chapter 2 Install the PowerMonitor 5000 Unit Optional ControlNet Communications An optional ControlNet port can be factory-installed in PowerMonitor 5000 units with a catalog number ending in -CNT, and can also be purchased from Rockwell Automation and installed by the user. ATTENTION: Power must be removed from the power monitor before inserting or removing an optional communication card. Inserting or removing an optional communication card under power may damage the card or the power monitor.
Chapter 3 Setup Although the PowerMonitor 5000 unit ships from the factory with default settings, you need to configure it for your particular requirements. The PowerMonitor 5000 unit provides a built-in Web interface for monitoring and configuration through its native Ethernet communication port and its USB device port. You perform initial configuration by using the power monitor's builtin USB Web interface.
Chapter 3 Setup Open the Internet Explorer browser and browse to http://192.168.169.3. The PowerMonitor 5000 home page displays in your browser as shown below. The home page displays general information about the PowerMonitor 5000 unit. You can navigate by clicking folders and pages from the tree on the left.
Setup Chapter 3 Obtaining Access to the Configuration Pages The PowerMonitor 5000 unit initially has security disabled by default. If your power monitor's security is disabled, you can continue setting up the unit without logging in. If Security is Enabled If security is enabled, the web page header displays ‘Logged in as:’ and a Log in link. If security is enabled, you need to log in as an administrator to configure setup parameters.
Chapter 3 Setup How to Set Up the PowerMonitor 5000 Unit From any power monitor web page, click the Configuration folder. A list of available configuration pages is displayed in the tree. The steps for entering, editing, and applying configuration parameters are similar for each configuration page. The configuration parameters and their properties are described nin the following chapters: • Chapter 4, Metering.
Setup EXAMPLE Chapter 3 This Metering_Basic page illustrates the setup for a 480V, 3-phase system with 1000:5 current transformer (CT) ratios on all phases and the neutral. Native Ethernet Communication Setup Choose the Configuration folder and choose the CommunicationsNative page. The PowerMonitor 5000 unit is set up by default to obtain an IP address automatically from a DHCP (Dynamic Host Configuration Protocol) server.
Chapter 3 Setup EXAMPLE This example explains how to change from a DHCP-assigned to a static IP address. The initial network configuration is shown below. The IP address assigned is 192.168.200.8. The network administrator has provided a range of static IP addresses in the same subnet, beginning with 192.168.200.100. In this case, the default gateway and DNS servers remain the same for static or DHCPobtained addresses (verify if this is true in your case with your network administrator).
Setup Chapter 3 Optional DeviceNet Communication Setup Choose the Configuration folder and choose the OptionalComm page, which lets you set the address and communication rate to operate in your system. The range for DeviceNet_Address is 0…63 (default). The selections for DeviceNet_Baudrate are the following: • 0 = 125 Kbps (default) • 1 = 250 Kbps • 2 = 500 Kbps • 3 = Autobaud Refer to Optional DeviceNet Communication on page 182 for more information on optional DeviceNet communication parameters.
Chapter 3 Setup Set Up Initial Security If you choose to enable security on the power monitor, you must perform the initial security setup by using the USB Web interface. 1. In the USB web page, choose the Security folder and then the Security page. 2. From the Security Defaults pull-down menu, choose Enable Security. 3. Accept the prompt regarding enabling security and accept the prompt to reload the web pages. 4. Log in with user name usbadmin and password usbadmin. 5.
Setup Chapter 3 7. Enter a username and password for a network administrator. The username and password can be any string up to 32 characters in length. This example sets a username of admin with a password of admin. Make a note of the new network administrator login for future use and keep it in a secure location.
Chapter 3 Setup Note that only the USB Web interface can be used to enable, disable, or reset security. If security accounts are lost or forgotten, you need to connect to the USB Web interface and log in with the usbadmin account to create new network security accounts. Setting Up Remaining Functions of the PowerMonitor 5000 Unit The remaining functions are set up in the same way as the examples discussed in this section.
Chapter 4 Metering Topic Page Basic Metering 51 Wiring Diagnostics 53 Wiring Correction 57 Metering Overview 60 Energy Metering 61 Demand Metering 62 Power Metering 67 Voltage, Current, Frequency Metering 69 Configuration Lock 71 This section describes the functions of the PowerMonitor 5000 unit. Most functions require you to configure set-up parameters to align the unit with your installation and your application requirements.
Chapter 4 Metering Set-up Parameters The following set-up parameters specify the configuration of the voltage and current sensing circuit, how the metered values are scaled, nominal values, update rate, and averaging. These parameters are found in the power monitor's Configuration > Metering_Basic web page. Metering_Mode Metering_Mode must match the external electrical system and how it is wired to the PowerMonitor voltage and current input terminals. Refer to the wiring diagrams in Chapter 2.
Metering Chapter 4 Realtime_Update_Rate This parameter specifies the averaging used and the update rate of metering results to the data tables and setpoint calculations.
Chapter 4 Metering The power monitor displays wiring diagnostic status results for all three power factor ranges when a command is issued. You decide which power factor range applies based upon your knowledge of the circuit and its load characteristics. You can expect more reliable wiring diagnostic results when the circuit is operating in a normal condition, that is, not especially lightly loaded. Figure 21 illustrates the part power factor plays in wiring diagnostics.
Metering Chapter 4 Command Command Word 2 Set this command word value to 11 (decimal) or make selection in web page to initiate wiring diagnostics. Wiring Diagnostic Results The PowerMonitor 5000 unit returns the following wiring diagnostic results for all three power factor ranges. Results are available for about 5 minutes after the command is received.
Chapter 4 Metering RangeN_Voltage_Input_Inverted RangeN_Current_Input_Inverted These are the values: -1 = Test not run 0 = Test passed 1 = Phase 1 inverted 2 = Phase 2 inverted 3 = Phase 3 inverted 12 = Phase 1 and 2 inverted 13 = Phase 1 and 3 inverted 23 = Phase 2 and 3 inverted 123 = All phases inverted Voltage_Rotation Current_Rotation These are the values: 123…321 designating phase and rotation.
Metering Chapter 4 Semantics Magnitudes are the scaled RMS value of the voltage or current. In Wye and splitphase modes, voltages are reported as line-to-neutral. In Delta modes, voltage is reported as line-to-line. Phase angles are referenced to Phase 1 Voltage, which is defined as zero, consistent with the 4-quadrant metering diagram included in Power Metering on page 67.
Chapter 4 Metering Applications This applies to all models. Setup Only basic metering setup is required. Command The Command.Wiring_Corrections table comprises the following parameters. Wiring_Correction_Commands Wiring_Correction_Commands determines the type of wiring correction to be performed when the command executes.
Metering Chapter 4 Status The Status.Wiring_Corrections table mirrors the parameters of the most recent wiring correction command. In addition, the following parameters report the status of the most recent command. Last_Cmd_Rejection_Status These are the values: 0 = No rejection 1 = Rejected; see rejection information Rejection_Information These are the values: 0 = No information 1 = Selected range is incomplete 2 = Command is already active.
Chapter 4 Metering Metering Overview The PowerMonitor 5000 unit performs calculations on scaled, digital voltage, and current values. Signals connected to the voltage and current inputs are sampled and their instantaneous values are converted to digital values in an analog-to-digital (A/D) converter section. These values are scaled according to configured PT Primary, PT Secondary, CT Primary, and CT Secondary parameters, and evaluated according to the configured Wiring Mode parameter.
Metering Energy Metering Chapter 4 The power monitor meters the following energy consumption parameters: • Real Energy Consumption (kWh, GWH), Forward, Reverse, Net • Reactive Energy Consumption (kVARh, GVARh) Forward, Reverse, Net • Apparent Energy Consumption (kVAh, GVAh) Net • Current Consumption (Amp-h) Applications This function applies to all PowerMonitor 5000 models.
Chapter 4 Metering Commands The following commands are supported by the power monitor: • Set GWh/kWh register • Set GVARh/kVARh register • Set GVAh/kVAh register • Clear all energy registers Related Functions • KYZ output • Energy log • Configuration lock Demand is an electric power term that expresses the average energy usage over a predefined period of time. The power monitor can be configured to measure demand by using a fixed demand period or a sliding window.
Metering Chapter 4 Demand power factor is calculated by using the following formula. kWDemand-------------------------------kVADemand Demand Calculation Demand is equal to the average power level during a predefined time interval. This interval continuously repeats and is typically 15 minutes but can be between 5 and 30 minutes in length. The power monitor computes demand levels for watts, VA, amps, and VARs, and provides two different methods for projecting demand.
Chapter 4 Metering Instantaneous The power monitor computes instantaneous demand by substituting the elapsed interval duration for the total interval duration (T) in the demand equation. It is therefore identical to the standard computation except it integrates the power only over the elapsed interval duration and calculates the average value over the elapsed duration.
Metering Chapter 4 These are the semantics: • If Demand_Broadcast_Mode_Select is set to master, then a Demand Source value of 0…2 selects the EOI source that is used to trigger the demand-sync master broadcast. • If Demand_Broadcast_Mode_Select is set to slave, then a Demand Source value of 0…3 selects the EOI source. Demand_Period_Length (Minutes) Specifies the desired period for demand calculations.
Chapter 4 Metering Demand_Broadcast_Mode_Select Demand Ethernet broadcast selection. These are the values: 0 = Slave (default) 1 = Master IMPORTANT There must be only one master per demand network. Demand_Broadcast_Port The common port for demand broadcast messages.
Metering Power Metering Chapter 4 This function applies to all PowerMonitor 5000 models. Table 10 - Power Metering Metered Parameters Parameter Description Range Units L1_kW Power of individual phase or sum of phases; signed to show direction -9.999E15…9.999E15 kW Reactive power of individual phase or sum of all phases; signed to show direction -9.999E15…9.999E15 kVAR Apparent power of individual phase or sum of all phases 0…9.
Chapter 4 Metering The Magnitude and Direction of Power Quantities chart indicates the relationship between the magnitude and direction of the power quantities and the numeric signs used by the power monitor.
Metering Voltage, Current, Frequency Metering Chapter 4 This function applies to all PowerMonitor 5000 models. Table 11 - Voltage, Current, and Frequency Metering Metered Parameters Parameter Description Range Units V1_N_Volts RMS line to neutral voltage of individual phase or average of V1, V2, V3 0…9.999E15 V VN_G_Volts RMS ground to neutral voltage 0…9.999E15 V V1_V2_Volts RMS line to line voltage of individual phase or average of V1_V2, V2_V3 and V3_V1 0…9.
Chapter 4 Metering Symmetrical Component Analysis Results The power monitor calculates sequence voltages and currents for use in symmetrical component analysis, which transforms a set of unbalanced threephase vectors into three sets of balanced vectors. The positive sequence components are a set of vectors that rotate the same direction as the original power vectors, and represent that portion of the applied voltage or current capable of doing work.
Metering Chapter 4 You can use the Web interface to view power quality results, power monitor status and statistics, and configuration. CalibrationData links to a printable calibration certificate for the power monitor. Configuration lets you review the configuration parameters, and, if logged in as an administrator, change them. While logged in as an administrator, you can also issue commands to the power monitor from the Command link.
Chapter 4 Metering Command.System_Registers • • • • • • Command Word 1, which includes the following commands: Set kWh, kVARh, kVAh, all energy registers Set status input count Force KYZ output on, off, or clear force Restore factory defaults Reset power monitor Setup No setup is needed.
Chapter 5 Power Quality Monitoring a Topic Page Harmonic Analysis 75 Sag and Swell Detection 79 Power Quality Event Classification (M6 model) 81 Short Duration RMS Variations (Category 2.0 - Sags, Swells, and Interruptions) (M6 model) 82 Long Duration RMS Variations (Category 3.0 - Undervoltage, Overvoltage, Sustained Interruptions) (M6 model) 84 Power Quality Event Example 85 Voltage and Current Imbalance (Category 4.0) 87 Waveform Distortion (Category 5.1 - DC Offset, and 5.
Chapter 5 Power Quality Monitoring The term ‘power quality’ is associated with electromagnetic irregularities in voltage and current in a power circuit that can interfere with or cause failures of electronic equipment. A number of national and international standards have been developed that define and classify power quality events and issues, and provide guidelines for detecting and reporting these events and issues.
Power Quality Monitoring Harmonic Analysis Chapter 5 The PowerMonitor 5000 provides harmonic data to help you understand this important element of power quality in your facility. Setup Only basic metering setup is required. Operation - IEEE and IEC Total Harmonic Distortion These total harmonic distortion calculation methods provide a summary indication of the amount of distortion due to harmonics present in a system.
Chapter 5 Power Quality Monitoring The increased losses are related to the square of the harmonic frequency. Therefore, a slight harmonic content can significantly increase the heat rise in a power transformer. The additional harmonic heating can cause a transformer to exceed designed temperature limits even though the RMS current is less than the transformer rating.
Power Quality Monitoring Chapter 5 Table 13 - Harmonic Analysis Results Tag Name Units Range I1_Crest_Factor 0…9.999E15 I2_Crest_Factor 0…9.999E15 I3_Crest_Factor 0…9.999E15 I4_Crest_Factor 0 …9.999E15 V1_IEEE_THD_% % 0.00…100.00 V2_IEEE_THD_% % 0.00…100.00 V3_IEEE_THD_% % 0.00…100.00 VN_G_IEEE_THD_% % 0.00 …100.00 Avg_IEEE_THD_V_% % 0.00…100.00 V1_V2_IEEE_THD_% % 0.00…100.00 V2_V3_IEEE_THD_% % 0.00…100.00 V3_V1_IEEE_THD_% % 0.00 …100.00 Avg_IEEE_THD_V_V_% % 0.00…100.
Chapter 5 Power Quality Monitoring Individual harmonic results are returned in an array of data tables. You can view any harmonic results table by selecting it from the PowerQuality > Harmonics_Results tab in the PowerMonitor 5000 web page. The available harmonic results data tables are listed below. • PowerQuality.Total_kW_H1_RMS (DC…31) • PowerQuality.Total_kW_H2_RMS (32…63) • PowerQuality.Total_kVAR_H1_RMS (DC…31) • PowerQuality.Total_kVAR_H2_RMS (32…63) • PowerQuality.
Power Quality Monitoring • • • • • • • • • • • • • • • • • • • • • • • • • • • • • • Sag and Swell Detection Chapter 5 PowerQuality.L3_kVAR_H1_RMS (DC…31) PowerQuality.L3_kVAR_H2_RMS (32…63) PowerQuality.L1_kVA_H1_RMS (DC…31) PowerQuality.L1_kVA_H2_RMS (32…63) PowerQuality.L2_kVA_H1_RMS (DC…31) PowerQuality.L2_kVA_H2_RMS (32…63) PowerQuality.L3_kVA_H1_RMS (DC…31) PowerQuality.L3_kVA_H2_RMS (32…63) PowerQuality.V1_N_Volts_H1_Ang (DC…31) PowerQuality.V1_N_Volts_H2_Ang (32…63) PowerQuality.
Chapter 5 Power Quality Monitoring Operation The power monitor detects and annunciates a sag when any phase voltage varies below the sag threshold. The sag indication continues for 90 seconds after the event is detected. A swell is indicated when any phase voltage exceeds the swell threshold. The indication continues until 90 seconds has elapsed after all phase voltages return to the threshold level.
Power Quality Monitoring Chapter 5 IEEE 1159-2009, Recommended Practice for Monitoring Electric Power Quality, categorizes various power quality events based on the parameters of the event such as voltage change, frequency content, rise time, event duration, etc. The table below, excerpted from the standard, summarizes the classifications in the recommended practice. Power Quality Event Classification (M6 model) IMPORTANT Table 14 is excerpted from standard IEEE 1159-2009 and is used with permission.
Chapter 5 Power Quality Monitoring Table 14 - Categories and Typical Characteristics of Power System Electromagnetic Phenomena(1) Categories Typical Spectral Content Typical Duration 5.2 Harmonics 0-9 kHz steady state 0-20% 5.3 Interharmonics 0-9 kHz steady state 0-2% 5.4 Notching Typical Voltage Magnitude steady state 5.5 Noise broadband steady state 0-1% 6.0 Voltage fluctuations < 25 Hz intermittent 0.1-7% < 10 s ± 0.10 Hz 0.2-2 Pstb 7.
Power Quality Monitoring Chapter 5 Table 15 - Sag and Swell Configuration Parameters Parameter Default Range Sag5_Hysteresis_% 2 0.00…10.00 Swell1_Trip_Point_% 110 100.00…200.00 Swell1_Hysteresis_% 2 0.00…10.00 Swell2_Trip_Point_% 120 100.00…200.00 Swell2_Hysteresis_% 2 0.00…10.00 Swell3_Trip_Point_% 140 100.00…200.00 Swell3_Hysteresis_% 2 0.00…10.00 Swell4_Trip_Point_% 180 100.00…200.00 Swell4_Hysteresis_% 2 0.00…10.
Chapter 5 Power Quality Monitoring A sag or swell with a duration that exceeds one minute is classified as an Long Duration RMS undervoltage or overvoltage, respectively. An interruption with a duration that Variations (Category 3.0 exceeds one minute is classified as a sustained interruption. Undervoltage, Overvoltage, Sustained Interruptions) (M6 Setup model) These Sag and Swell parameters also determine that operation of undervoltage and overvoltage detection.
Power Quality Monitoring Power Quality Event Example Chapter 5 This example illustrates the actions taken by the PowerMonitor 5000 M6 model in response to various types of power quality events. t8 V 1 Rms % of nominal 120 T 8 + 90 s ec t7 100 T9 + 90 s ec 120 t6 60 t5 t4 40 t1 t2 t3 t9 70 10 180 240 300 Alarm tags Sag_Indication _Detected 1 0 Swell_Indication _Detected 1 0 IEEE 1159_Under_Voltage_V1 1 0 Time (seconds ) Three waveforms are captured in this example.
Chapter 5 Power Quality Monitoring Waveform B represents the third sag, which occurs after the first waveform recording reached its maximum duration and ended. Pre Event Post Event 80% Sag t6 t5 Waveform C represents the swell following the interruption. Pre Event Post Event Swell t8 t9 The power quality log includes the following events. The log records have been simplified to make the example clearer.
Power Quality Monitoring Voltage and Current Imbalance (Category 4.0) Chapter 5 The PowerMonitor 5000 includes long-term voltage and current unbalance in its metering results. The M6 model reports voltage and current imbalance as power quality events. Setup Basic metering setup is required. These configuration parameters are found in the Configuration.
Chapter 5 Power Quality Monitoring Waveform Distortion (Category 5.1 - DC Offset, and 5.2 - Harmonics) (M6 model) The PowerMonitor 5000 M6 model detects and reports long-term waveform distortion in excess of configured limits. Categories 5.3, 5.4 and 5.5 are not supported in the M6 model. Setup Basic metering setup required. These configuration parameters are found in the Configuration.
Power Quality Monitoring Chapter 5 Related Functions • Harmonic Analysis • Power Quality Log Power Frequency Variations (Category 7.0) The PowerMonitor 5000 M6 model detects and reports short-term power frequency variations in excess of configured limits. Setup Basic metering setup is required. These configuration parameters are found in the Configuration.
Chapter 5 Power Quality Monitoring IEEE 519 Pass/Fail Capability (M6 model) IEEE 519-1992, the standard for Recommended Practices and Requirements for Harmonic Control in Electrical Power Systems, provides recommended limits for the level of harmonics in a circuit. The standard applies these limits to current and voltage harmonics up to the 40th order present at the Point of Common Coupling (PCC) between your electric power supplier and your facility, typically where utility meters are connected.
Power Quality Monitoring Chapter 5 Setup Basic Metering setup is required. Three configuration parameters required for calculating the IEEE 519 Pass/Fail requirements are found in the Configuration.PowerQuality tab. • IEEE519_Compliance_Parameter - Selects 0 = current (default) or 1 = voltage as the compliance parameter. • IEEE519_MAX_Isc_Amps - Short circuit current available at the PCC, in Amps.
Chapter 5 Power Quality Monitoring These bitfields reports the short-term or long-term status of harmonics of order 18…33. • • • • • • 0 = PASS 1 = FAIL Bit0 - 18th_Harmonic_PASS_FAIL Bit1 - 19th_Harmonic_PASS_FAIL … Bit15 - 33rd_Harmonic_PASS_FAIL ShortTerm_34th_To_40th_Harmonic_Status LongTerm_34th_To_40th_Harmonic_Status These bitfields reports the short-term or long-term status of harmonics of order 34 through 40.
Power Quality Monitoring Chapter 5 Refer to the PowerMonitor 5000 Unit Data Tables on page 225 for further details on these data tables. Related Functions • Harmonic Analysis • Alarm Log Waveform Recording (M6 model) The PowerMonitor 5000 M6 model can capture and record waveforms of all current and voltage channels. Setup Basic metering setup is required. These configuration parameters are found in the Configuration.
Chapter 5 Power Quality Monitoring Waveform capture is triggered in three ways: • Manually, through a command • Automatically by the power monitor when it detects a sag or swell event • In response to a waveform synchronization broadcast message Waveform triggers are ignored when insufficient space remains to store a new waveform. Waveform files can be cleared by using the Clear_Waveform command. See Commands on page 95. The waveform voltage source depends on the Metering_Mode parameter value.
Power Quality Monitoring Chapter 5 Waveform Capture Application Considerations The PowerMonitor 5000 captures one waveform record at a time. It is possible that more than one triggering event can occur in a short time. The starting point of a waveform capture is determined by the first triggering event and the defined pre-event cycles. If fewer cycles of data are available, then the first available cycle is the starting point.
Chapter 5 Power Quality Monitoring Waveform File Names Waveform files are stored with names that contain file identification and a local timestamp.
Power Quality Monitoring Chapter 5 Reading Waveform Records by Using the Data Table Interface The procedure for reading waveform records is similar to that used for reading data logging records. Refer to Reading Logging Records by Using the Data Table Interface on page 103.
Chapter 5 Power Quality Monitoring Notes: 98 Rockwell Automation Publication 1426-UM001F-EN-P - November 2013
Chapter 6 Logging Topic Page Logging Overview 100 Waveform Log (M6 Model) 105 Energy Log 109 Data Log 113 Min/Max Log 123 Load Factor Log 126 Time-of-use (TOU) Log 128 Event Log 130 Setpoint Log 134 Alarm Log 136 Power Quality Log (M6 model) 141 Trigger Data Log (M6 model) 145 Snapshot Log 148 This section describes the functions of the PowerMonitor 5000 unit.
Chapter 6 Logging The PowerMonitor 5000 unit maintains a number of types of internal data logs and records metering, status, event, and alarm data into these logs as specified in the logging configuration. This table summarizes the data log types and sizes, and how their records can be retrieved.
Logging Chapter 6 Setpoint_Log_Mode Setpoint_Log_Mode defines the log behavior when full. 0 = Stop logging 1 = Overwrite oldest record Time_Of_Use_AutoStore Time_Of_Use_AutoStore defines the day of the month to start a new time-ofuse log record. Off_Peak_Days Off_Peak_Days is a bit field that specifies off-peak days of the week.
Chapter 6 Logging Event_Log_Mode Event_Log_Mode defines the log behavior when full. 0 = Stop logging. 1 = Overwrite oldest record. Retrieve Logging Results from Web Page You can retrieve logging results from the PowerMonitor 5000 web page. Browse to the network address of the power monitor. From the home page, choose the LoggingResults folder and then the Data_Log or another logging results page. To retrieve a file, click the filename link.
Logging Chapter 6 Download Logging Results by Using FTP You can retrieve tlogging results by using File Transfer Protocol (ftp). There are many ftp clients available, many at no charge. This example uses the Microsoft Windows command-line ftp client. To access log files by using this client, follow these steps. 1. From the Windows Start menu, choose Run. 2. Type cmd and click OK. 3. At the prompt, type ftp and press Enter (this time and after each command). 4. Type ‘open aaa.bbb.ccc.
Chapter 6 Logging The Data, Energy, Waveform, and Trigger Data logs support sequential record retrieval but require additional configuration steps. See Energy Log on page 109, Waveform Log (M6 Model) on page 105, Data Log on page 113, and Trigger Data Log (M6 model) on page 145 for more information. IMPORTANT Sequential record retrieval is available for networks such as DeviceNet that do not support ftp.
Logging Chapter 6 Min/Max Record to be Returned These are the choices: 0 = Use sequential return in the order selected 1…82 = Retrieve the selected record.
Chapter 6 Logging 2. Write the Configuration.Log_Read table with Selected Log = 11. The Configuration.LogRead table contains the following elements: • Element 0. Write a value of 11 to request the next waveform file name • Element 1: Write a 0 to return the most recent file name first or a 1 to return the oldest file name first 3. Read the waveform file name from the LoggingResults.WaveformFileName table one or more times until the desired waveform file name is returned. The LoggingResults.
Logging Chapter 6 Waveform Data Records The LoggingResults.Waveform_Log table contains the most recent record read from the selected waveform file, and contains the following REAL elements.
Chapter 6 Logging Waveform Header If the value of Record_Indicator is 2, the LoggingResults.Waveform_Log table returns the following information. The data type returned is REAL, although some elements (MAC ID) are better interpreted as UINT32.
Logging Energy Log Chapter 6 The energy log stores energy, demand, and scaled status input counter values at a time interval defined in parameter Energy_Log_Interval. The power monitor can store up to 90 days of energy log data. The default logging interval is 15 minutes. Energy Log Results Files The PowerMonitor 5000 unit stores the energy log in multiple commaseparated-value (.csv) files, and selects a file duration based on the value of the Energy_Log_Interval parameter.
Chapter 6 Logging Logged Parameters The energy log records a predefined set of parameters. The first record in each file is a header that indicates the tag name of each parameter. Each subsequent record is a structure of REAL elements containing the following parameters.
Logging Chapter 6 Energy Log Single Record Retrieval A controller or application can sequentially retrieve records from the Energy Log files by following the process described in this section, following these general tasks. 1. Read the number of log files from the Statistics.Logging table. 2. Write the Configuration.Log_Read table and read the filename from the LoggingResults.EnergyLog_FileName table until the desired log file is selected. 3. Write the selected file name into the Configuration.
Chapter 6 Logging The LoggingResults_EnergyLog table contains the most recent record read from the selected energy log file, and contains the following elements: • Element 0 indicates the type of record Options are: – 0 = No record returned – 1 = Parameter values – 2 = Reserved – 3 = Log file not found • Element 1 returns a unique record ID. • Elements 2…5 return the date and time stamp of the record • Elements 6…37 return parameter values.
Logging Data Log Chapter 6 The data log stores user-selected values at a time interval defined in parameter Data_Logging_Interval. The power monitor can store up to 60,000 records of up to 32 parameters. The default logging interval is 15 minutes. Setup The Data Log requires the following to be configured: • Basic metering setup • Date and Time setup The first 22 parameters in the Data Log are configured by default, as listed in the Logged Parameters table.
Chapter 6 Logging Data Log Parameter List Table 19 - Data Log Parameter List 114 Parameter Number Parameter Tag Name Units 0 None 1 V1_N_Volts V 2 V2_N_Volts V 3 V3_N_Volts V 4 VGN_N_Volts V 5 Avg_V_N_Volts V 6 V1_V2_Volts V 7 V2_V3_Volts V 8 V3_V1_Volts V 9 Avg_VL_VL_Volts V 10 I1_Amps A 11 I2_Amps A 12 I3_Amps A 13 I4_Amps A 14 Avg_Amps A 15 Frequency_Hz Hz 16 L1_kW kW 17 L2_kW kW 18 L3_kW kW 19 Total_kW kW 20 L1_kVAR kVAR 21 L2_kVAR k
Logging Chapter 6 Table 19 - Data Log Parameter List Parameter Number Parameter Tag Name Units 37 L2_PF_Lead_Lag_Indicator % 38 L3_PF_Lead_Lag_Indicator % 39 Total_PF_Lead_Lag_Indicator % 40 V1_Crest_Factor CF 41 V2_Crest_Factor CF 42 V3_Crest_Factor CF 43 V1_V2_Crest_Factor CF 44 V2_V3_Crest_Factor CF 45 V3_V1_Crest_Factor CF 46 I1_Crest_Factor CF 47 I2_Crest_Factor CF 48 I3_Crest_Factor CF 49 I4_Crest_Factor CF 50 V1_IEEE_THD_% % 51 V2_IEEE_THD_% % 52 V3_
Chapter 6 Logging Table 19 - Data Log Parameter List 116 Parameter Number Parameter Tag Name Units 76 I4_IEC_THD_% % 77 Avg_IEC_THD_I_% % 78 I1_K_Factor KF 79 I2_K_Factor KF 80 I3_K_Factor KF 81 Pos_Seq_Volts V 82 Neg_Seq_Volts V 83 Zero_Seq_Volts V 84 Pos_Seq_Amps A 85 Neg_Seq_Amps A 86 Zero_Seq_Amps A 87 Voltage_Unbalance_% % 88 Current_Unbalance_% % 89 V1_N_Volts_DC_H_RMS V 90 V1_N_Volts_1st_H_RMS V 91 V1_N_Volts_2nd_H_RMS V 92 V1_N_Volts_3rd_H_RMS
Logging Chapter 6 Table 19 - Data Log Parameter List Parameter Number Parameter Tag Name Units 115 V1_N_Volts_26th_H_RMS V 116 V1_N_Volts_27th_H_RMS V 117 V1_N_Volts_28th_H_RMS V 118 V1_N_Volts_29th_H_RMS V 119 V1_N_Volts_30th_H_RMS V 120 V1_N_Volts_31st_H_RMS V 121 V2_N_Volts_DC_H_RMS V 122 V2_N_Volts_1st_H_RMS V 123 V2_N_Volts_2nd_H_RMS V 124 V2_N_Volts_3rd_H_RMS V 125 V2_N_Volts_4th_H_RMS V 126 V2_N_Volts_5th_H_RMS V 127 V2_N_Volts_6th_H_RMS V 128 V2_N_Volts_7
Chapter 6 Logging Table 19 - Data Log Parameter List 118 Parameter Number Parameter Tag Name Units 154 V3_N_Volts_1st_H_RMS V 155 V3_N_Volts_2nd_H_RMS V 156 V3_N_Volts_3rd_H_RMS V 157 V3_N_Volts_4th_H_RMS V 158 V3_N_Volts_5th_H_RMS V 159 V3_N_Volts_6th_H_RMS V 160 V3_N_Volts_7th_H_RMS V 161 V3_N_Volts_8th_H_RMS V 162 V3_N_Volts_9th_H_RMS V 163 V3_N_Volts_10th_H_RMS V 164 V3_N_Volts_11th_H_RMS V 165 V3_N_Volts_12th_H_RMS V 166 V3_N_Volts_13th_H_RMS V 167 V3_N_Vo
Logging Chapter 6 Data Log Results Files The PowerMonitor 5000 unit stores the data log in multiple comma-separatedvalue (.csv) files, and selects a file duration based on the value of the Data_Logging_Interval parameter.
Chapter 6 Logging Logged Parameters The data log records a user-selected set of parameters. The first record in each file is a header that indicates the tag name of each logged parameter. Each subsequent record is a structure of REAL elements containing the following parameters.
Logging Chapter 6 Table 20 - Data Log Logged Parameters Element Tag Name Description 25 DataLog_Parameter_21 26 DataLog_Parameter_22 Values of user-selected or default parameters 27 DataLog_Parameter_23 28 DataLog_Parameter_24 29 DataLog_Parameter_25 30 DataLog_Parameter_26 31 DataLog_Parameter_27 32 DataLog_Parameter_28 33 DataLog_Parameter_29 34 DataLog_Parameter_30 35 DataLog_Parameter_31 36 DataLog_Parameter_32 Data Log Single Record Retrieval A controller or application ca
Chapter 6 Logging The Configuration.DataLogFile table contains the file selection string.
Logging Min/Max Log Chapter 6 The PowerMonitor 5000 unit records time-stamped minimum and maximum values for all real-time metering data (except for energy data). Min/Max Log Results Min/max log records can be retrieved from the PowerMonitor 5000 web page or ftp server. The power monitor generates the log file at the time of the request. Records can also be retrieved individually or sequentially by using the data table interface. File Name The min/max log is named Min_Max_Log.csv.
Chapter 6 Logging Table 22 - Min/Max Log Parameter Attributes 124 Parameter No.
Logging Chapter 6 Table 22 - Min/Max Log Parameter Attributes Parameter No.
Chapter 6 Logging Setup The Min/Max Log requires the following to be configured: • Basic metering setup • Logging configuration • Date and Time setup Commands • Clear single min/max log record • Clear min/max log Related Functions • • • • Load Factor Log Demand metering Voltage, current and frequency metering Power metering Configuration lock The PowerMonitor 5000 unit maintains a 12-month record of real, reactive and apparent demand and load factor.
Logging Chapter 6 Logged Parameters The load factor log consists of 14 records. The first is a header naming the logged parameters. The second is an active record for the current month. The remaining records are static and store data for each of the previous 12 months. The monthly records operate in a circular, or FIFO fashion. On a user-selected day each month, the current record is pushed into the stack of monthly records and, if the stack is full, the oldest is deleted.
Chapter 6 Logging Time-of-use (TOU) Log The PowerMonitor 5000 unit maintains records of energy and demand organized by times of use defined by the user. In the PowerMonitor 5000 model, there are three time-of-use (TOU) logs, one each for real, reactive and apparent energy, and demand. Within each log, energy consumption and peak demand are recorded into off-peak, mid-peak and onpeak categories. The days and times that define the mid- and on-peak periods are user selectable.
Logging • • • • • • • • • • • • • • • • • Chapter 6 Off_Peak_kVARh_Net Off_Peak_kVAR_Demand Mid_Peak_GVARh_Net Mid_Peak_kVARh_Net Mid_Peak_kVAR_Demand On_Peak_GVARh_Net On_Peak_kVARh_Net On_Peak_kVAR_Demand Off_Peak _GVAh_Net Off_Peak_kVAh_Net Off_Peak_kVA_Demand Mid_Peak_GVAh_Net Mid_Peak_kVAh_Net Mid_Peak_kVA_Demand On_Peak_GVAh_Net On_Peak_kVAh_Net On_Peak_kVA_Demand Setup The Time-of-use Log requires the following to be configured: • Basic metering setup (including Demand) • Logging configuration •
Chapter 6 Logging Event Log The event log records the date and time of changes made to the device and of external events. The event log is up to 100 records deep. The event log cannot be cleared. The Event_Log_Mode parameter determines what happens when log is full: • If 0 = Stop logging, no more event data is logged. • If 1 = Overwrite oldest record, event logging continues and oldest events are deleted.
Logging Chapter 6 Table 24 - Event, General, and Information Codes Event Type Event # General Code Code Self-Test Status 1 Pass 0 Nor Flash Memory 1 Information Code Code Overall Status 1 Boot Code Checksum 2 Application Code Checksum 4 Wrong Application FRN 8 Invalid Model Type 16 WIN Mismatch 32 Missing Upgrade Block 64 SDRAM 2 Failed Read/Write Test 1 NAND Flash Memory 4 Read/Write Failed 1 FRAM 8 Failed Read/Write Test 1 Real Time Clock 16 Real Time Clock Failed
Chapter 6 Logging Table 24 - Event, General, and Information Codes Event Type Event # General Code Code Configuration Changed 2 Clock Set 1 Status Input Counter Set 2 Factory Defaults Restored 4 Energy Register Set 8 Information Code Code Status Input 1 1 Status Input 2 2 Status Input 3 4 Status Input 4 8 Wh Register 1 VARh Register 2 VAh Register 4 Ah Register 8 All Energy Registers Cleared 16 Log Cleared or Set Relay/KYZ Output Forced Status Input Activated 132 4 8
Logging Chapter 6 Table 24 - Event, General, and Information Codes Event Type Event # General Code Code Status Input Deactivated 32 Status Input 1 1 Status Input 2 2 Status Input 3 4 Status Input 4 8 Wh Register 1 VARh Register 2 VAh Register 4 Status Input 1 Register 8 Status Input 2 Register 16 Status Input 3 Register 32 Status Input 4 Register 64 Energy Register Rollover 64 Device Power Up 128 Device Power Down 256 Missed External Demand Sync 512 Register Set Clear
Chapter 6 Logging Setpoint Log The setpoint log records information when a setpoint output activates (asserts) or deactivates (de-asserts). The setpoint log is up to100 records deep. The Setpoint_Log_Mode parameter determines what happens when log is full: • If 0 = Stop logging, no more setpoint data is logged. • If 1 = Overwrite oldest record, logging continues and oldest events are deleted. Setpoint Log Results Setpoint log records can be retrieved from the PowerMonitor 5000 web page or ftp server.
Logging Chapter 6 Table 25 - Setpoint Log Logged Parameters Item Name Description Output_Action Configured action when actuated. Accumulated_Time Total accumulation in seconds. Number_Of_Transitions Number of transitions from off to on.
Chapter 6 Logging Alarm Log The alarm log records information when an alarm occurs. The alarm log is up to 100 records deep. The alarm log cannot be cleared. Alarm Log Results Alarm log records can be retrieved from the PowerMonitor 5000 web page or ftp server. Alarm log records can also be retrieved sequentially by using the data table interface. File Name The alarm log is named Alarm_Log.csv. Logged Parameters The alarm log operates in a circular, or FIFO fashion.
Logging Chapter 6 Table 27 - Alarm Codes and Descriptions Alarm Type Description Type Alarm Code Description Code Metering_Status 1 Virtual_Wiring_Correction 1 Voltage_Phase_V1 2 Voltage_Phase_V2 4 Voltage_Phase_V3 8 Voltage_Over_Range_Indication 16 Ampere_Over_Range_Indication 32 Wiring_Diagnostics_Active 64 V1G_Over_Range 1 V2G_Over_Range 2 V3G_Over_Range 4 VNG_Over_Range 8 I1_Over_Range 16 I2_Over_Range 32 I3_Over_Range 64 I4_Over_Range 128 Sag_Indication_Detected 1
Chapter 6 Logging Table 27 - Alarm Codes and Descriptions Alarm Type Description Type Alarm Code Description Code IEEE1159_DCOffset_THD_Frequency_Con dition 64 IEEE1159_DCOffset_Condition_V1 1 IEEE1159_DCOffset_Condition_V2 2 IEEE1159_DCOffset_Condition_V3 4 IEEE1159_Voltage_THD_Condition_V1 8 IEEE1159_Voltage_THD_Condition_V2 16 IEEE1159_Voltage_THD_Condition_V3 32 IEEE1159_Current_THD_Condition_ I1 64 IEEE1159_Current_THD_Condition_ I2 128 IEEE1159_Current_THD_Condition_ I3 256 I
Logging Chapter 6 Table 27 - Alarm Codes and Descriptions Alarm Type Description Type Alarm Code Description Code ShortTerm_18th_To_33rd_Harmonic_St atus 512 18th_Harmonic_PASS_FAIL 1 19th_Harmonic_PASS_FAIL 2 20th_Harmonic_PASS_FAIL 4 21st_Harmonic_PASS_FAIL 8 22nd_Harmonic_PASS_FAIL 16 23rd_Harmonic_PASS_FAIL 32 24th_Harmonic_PASS_FAIL 64 25th_Harmonic_PASS_FAIL 128 26th_Harmonic_PASS_FAIL 256 27th_Harmonic_PASS_FAIL 512 28th_Harmonic_PASS_FAIL 1024 29th_Harmonic_PASS_FAIL 2
Chapter 6 Logging Table 27 - Alarm Codes and Descriptions Alarm Type Description Type Alarm Code Description Code LongTerm_18th_To_33rd_Harmonic_Sta tus 4096 18th_Harmonic_PASS_FAIL 1 19th_Harmonic_PASS_FAIL 2 20th_Harmonic_PASS_FAIL 4 21st_Harmonic_PASS_FAIL 8 22nd_Harmonic_PASS_FAIL 16 23rd_Harmonic_PASS_FAIL 32 24th_Harmonic_PASS_FAIL 64 25th_Harmonic_PASS_FAIL 128 26th_Harmonic_PASS_FAIL 256 27th_Harmonic_PASS_FAIL 512 28th_Harmonic_PASS_FAIL 1024 29th_Harmonic_PASS_FAIL 2
Logging Power Quality Log (M6 model) Chapter 6 The PowerMonitor 5000 M6 model records power quality events that it has detected and classified into a Power Quality log. Setup • Basic metering setup • Date and time setup • Logging configuration The Power_Quality_Log_Mode parameter in the Configuration.Logging tab determines what happens when the log is full: • 0 = Stop logging; no more power quality data is logged. • 1 = Overwrite oldest record; logging continues and oldest events are deleted.
Chapter 6 Logging Logged Parameters The event log operates in a circular, or FIFO fashion. When accessed as a file, the first record is a header containing the tag names. Each subsequent record is a structure of REAL elements containing the following parameters. Tag Name Description Record_Identifier Used to verify record sequence when returning multiple records Event_Type Power quality event type, see Power Quality Event Code table. Sub_Event_Code Indicate the sub event of the event type.
Logging Chapter 6 Power Quality Event Codes Power Quality Event Name Event Code Sub Event Name Sub Event Code Can Trigger Waveform Capture Description Voltage_Swell 1 V1_Swell 1 • Voltage Swell (4 trip points for V1) V2_Swell 2 • Voltage Swell (4 trip points for V2) V3_Swell 3 • Voltage Swell (4 trip points for V3) V1_Sag 1 • Voltage Sag (5 trip points for V1) V2_Sag 2 • Voltage Sag (5 trip points for V2) V3_Sag 3 • Voltage Sag (5 trip points for V3) Voltage_Sag 2 Imbalan
Chapter 6 Logging Power Quality Log Results Power quality log records can be retrieved in a file from the PowerMonitor 5000 web page or ftp server. The link for the power quality log is found in the LoggingResults.General_Logs tab in the web page. To retrieve the file, click the link and follow the prompts to save or open the file. The ftp server works in a similar way.
Logging Trigger Data Log (M6 model) Chapter 6 A trigger data log is enabled as a setpoint or logic gate output action in the M6 model, and stores a cycle-by-cycle record of the values of up to 8 selected parameters for a selected duration when its associate setpoint activates.
Chapter 6 Logging File Names Triggerlog_YYYYMMDD_hhmmss_HH, and TriggerSetpointInfo_YYYYMMDD_hhmmss_HH, where • YYYMMDD_hhmmss = the local date and time stamp of the record, used to associate the trigger data file with its associated setpoint information • HH = the UTC hour avoids duplication during daylight-saving time transition Refer to Appendix A, LoggingResults. TriggerData_Header Data Table for the content and structure of the setpoint information file, and LoggingResults.
Logging Chapter 6 3. Read the trigger data setpoint information file name from the LoggingResults. TriggerLog_Setpoint_Info_File_Name (M6 model) table one or more times until the desired file name is returned. 4. Read the trigger data file name from the LoggingResults.TriggerLog_FileName Data Table one or more times until the desired file name is returned. 5. Write the selected file names into the Configuration.TriggerDataLogFile (M6 Model) and Configuration.TriggerSetpointInfoFile (M6 model) tables. 6.
Chapter 6 Logging Snapshot Log The Snapshot log captures a record of all data from a single cycle on command. Setup The Snapshot log requires the following to be configured: • Basic Metering setup • Date and Time setup Operation The Snapshot log captures and records the present cycle's data when a command is issued.
Logging Chapter 6 Web Interface Click the link and follow the prompts to save or open the log file. The Snapshot_ParameterList file lists the parameter IDs and their corresponding tag names. The ftp page is similar. Data Table Interface Successive reads of the LoggingResults.Snapshot_Log data table return sequential single parameters. The following is the data returned: • Parameter_Number - the ID number of the parameter. The Snapshot_ParameterList.
Chapter 6 Logging Notes: 150 Rockwell Automation Publication 1426-UM001F-EN-P - November 2013
Chapter 7 Logic Functions Topic Page Relay and KYZ Outputs 151 Status Inputs 155 Setpoints 157 This section describes the functions of the PowerMonitor 5000 unit. Most functions require you to configure set-up parameters to align the unit with your installation and your application requirements. The set-up parameters are listed by name and described in this section.
Chapter 7 Logic Functions Operation The outputs can operate in the following modes: • Energy pulse operation with fixed pulse width or toggle • Setpoint operation • I/O control through a Class 1 connection • Forced operation IMPORTANT I/O control can use relay output contacts and solid-state KYZ outputs on the PowerMonitor 5000 unit to control other devices. You can select the response of these outputs to a loss of the connection.
Logic Functions Chapter 7 KYZ_Solid_State_Output_Scale Output_Relay_1_Output_Scale Output_Relay_2_Output_Scale Output_Relay_3_Output_Scale The output parameter divided by the scale is the output pulse rate. Example: Wh is selected for the parameter and 1,000 is the scale value. The output is pulsed every 1000 Wh, or 1 kWh. This parameter is ignored for setpoint or communication operation.
Chapter 7 Logic Functions Semantics of selections: • Last-state = hold the output in its last state on communication loss • De-energize = put output into de-energized or normal state on communication loss • Resume = restore output control when communication recovers • Freeze = maintain state of output when communication recovers until one of the following occurs: – Logic controller enters program mode – Power cycle to the power monitor – Change the parameter value to ‘resume’ • Local Control = Revert to l
Logic Functions Chapter 7 Set this command word value to execute the corresponding action.
Chapter 7 Logic Functions Log_Status_Input_Changes These are the choices: 0 = Disable recording of status input changes into the status log 1 = Enable recording of event input changes into the status log Status_Input_1_Input_Scale Status_Input_2_Input_Scale Status_Input_3_Input_Scale Status_Input_4_Input_Scale When a status pulse is received the count is increased by the scale factor. (Input pulse * input scale) added to total status count.
Logic Functions Chapter 7 Commands The following command parameters are found in the Command.System_Registers table. Command Word 1 Set this command word value to set or reset (to zero) a scaled status input counter value. These are the selections: 6 = Set Status 1 Count 7 = Set Status 2 Count 8 = Set Status 3 Count 9 = Set Status 4 Count These commands operate by using the values contained in the tags listed below. The default values are zero.
Chapter 7 Logic Functions Operation A PowerMonitor 5000 unit setpoint continually monitors the selected parameter and evaluates its value against the configured test condition, evaluation types, threshold, and hysteresis values. The setpoint is armed when the parameter value satisfies the test condition. A setpoint activates when it has been armed for at least the assert delay time.
Logic Functions Chapter 7 Simple Setpoint Logic (all models) The PowerMonitor 5000 unit provides three test conditions for setpoint logic. Any parameter type is permitted to be used with any test condition. Be sure to test the operation of your setpoint setup to assure the desired operation.
Chapter 7 Logic Functions Equal To An Equal To test condition arms the setpoint for activation when the monitored value exactly equals the threshold, and dis-arms the setpoint when the value no longer equals the threshold. Hysteresis is ignored in the Equal To test condition. Figure 25 illustrates this. In Figure 25e, the setpoint is armed at point A, disarmed at point B, and armed at point C. Point d also arms the setpoint but the value changes at point e before the assert delay time passes.
Logic Functions Chapter 7 Operation • AND An AND gate output asserts when ALL of its enabled inputs are asserted. Disabled inputs are ignored. If only one input is enabled, the logic gate output copies the input state. • NAND A NAND, or Not-AND, gate output asserts except when ALL of its enabled inputs are asserted. Disabled inputs are ignored. If only one input is enabled, the logic gate output inverts the input state. • OR An OR gate output asserts when ANY of its enabled inputs are asserted.
Chapter 7 Logic Functions Reference Value n Used only when Evaluation Type n = 2, Percent of Reference; otherwise ignored.
Logic Functions Chapter 7 Relative_Setpoint_Interval_m This tag, found in the Configuration.PowerQuality table, defines the length of the sliding average interval used in all setpoints with Percent of Sliding Reference evaluation type. Range: 1 (default)…1440 minutes Setpoint Logic Gate Setup The tags listed below can be used to configure setpoint logic gates and are found in the Configuration.Setpoint_Logic Data Table. Logic Level 1 Gate n Function Selects the logic type for the gate.
Chapter 7 Logic Functions Setpoint Output n Input Source 1…10 = Setpoints 1…10 (M5 model) 11…20 = Setpoints 11…20 (M6 model) 21…30 = Level 1 Logic Gates 1…10 (M6 model) Setpoint Output n Action See Setpoint Output Action List on page 167 for selections. Setpoint Reference Tables Table 28 - Setpoint Parameter Selection List Parameter Number Parameter Tag Name Units Range 0 None 1 V1_N_Volts V 0…9.999E15 2 V2_N_Volts V 0…9.999E15 3 V3_N_Volts V 0…9.999E15 4 VG_N_Volts V 0…9.
Logic Functions Chapter 7 Table 28 - Setpoint Parameter Selection List Parameter Number Parameter Tag Name Units Range 31 Avg_True_PF % 0.00…100.00 36 L1_Disp_PF % 0.00…100.00 37 L2_Disp_PF % 0.00…100.00 38 L3_Disp_PF % 0.00…100.00 39 Avg_Disp_PF % 0.00…100.00 36 L1_PF_Lead_Lag_Indicator -1 or 1 37 L2_PF_Lead_Lag_Indicator -1 or 1 38 L3_PF_Lead_Lag_Indicator -1 or 1 39 Total_PF_Lead_Lag_Indicator -1 or 1 40 V1_Crest_Factor CF 0…9.999E15 41 V2_Crest_Factor CF 0…9.
Chapter 7 Logic Functions Table 28 - Setpoint Parameter Selection List Parameter Number Parameter Tag Name Units Range 76 I4_IEC_THD_% % 0.00…100.00 77 Avg_IEC_THD_I_% % 0.00…100.00 78 I1_K_Factor KF 0.00…1.00 79 I2_K_Factor KF 0.00…1.00 80 I3_K_Factor KF 0.00…1.00 81 Pos_Seq_Volts V 0…9.999E15 82 Neg_Seq_Volts V 0…9.999E15 83 Zero_Seq_Volts V 0…9.999E15 84 Pos_Seq_Amps A 0…9.999E15 85 Neg_Seq_Amps A 0…9.999E15 86 Zero_Seq_Amps A 0…9.
Logic Functions Chapter 7 Table 29 - Setpoint Output Action List Parameter Number Action Name 0 None 1 Energize Relay 1 2 Energize Relay 2 3 Energize Relay 3 4 Energize KYZ 5 Clear kWh result 6 Clear kVARh result 7 Clear kVAh result 8 Clear Ah result 9 Clear all energy results 10 Clear setpoint #1 time accumulator and transition count 11 Clear setpoint #2 time accumulator and transition count 12 Clear setpoint #3 time accumulator and transition count 13 Clear setpoint #4 time
Chapter 7 Logic Functions Setpoint and Logic Gate Status Setpoint status is reported in the following tags, found in the Status.Alarms table.
Logic Functions Chapter 7 Command Word 2 Set this command word value to execute the listed action. These are the selections: 6 = Clear Setpoint Log 7 = Clear Setpoint (Time) Accumulators 18 = Clear Setpoint Logic Gate (Time) Accumulators Clear Setpoint Accumulators operates by using the value contained in the tag listed below. The default value is zero.
Chapter 7 Logic Functions Notes: 170 Rockwell Automation Publication 1426-UM001F-EN-P - November 2013
Chapter 8 Other Functions Table Page Security 171 Date and Time Functions 173 Network Time Synchronization 175 System Error Response 178 Miscellaneous Commands 180 This section describes the functions of the PowerMonitor 5000 unit. Most functions require you to configure set-up parameters to align the unit with your installation and your application requirements. The set-up parameters are listed by name and described in this section.
Chapter 8 Other Functions Once security is enabled and an Admin class account is set up during initial configuration, the remaining security configuration can be done through the network web page. If you want to configure power monitors by using software, such as FactoryTalk EnergyMetrix RT software, set up at least one Application class account. This table summarizes the security classes, privileges, access, and limits that apply to the PowerMonitor 5000 unit.
Other Functions Chapter 8 If an Exclusive Owner connection has been set up between a Logix controller and the PowerMonitor 5000 unit, configuration of the power monitor is permitted only through the controller. Attempts to change configuration by using the web interface or other means returns an ownership conflict error. The PowerMonitor 5000 unit does not have a ‘backdoor’ password.
Chapter 8 Other Functions Date_Day These are the values: 1 (default)…31 Time_Hour These are the values: 0 (default)…23 Time_Minute These are the values: 0 (default)…59 Time_Seconds These are the values: 0 (default)…59 Time_Milliseconds These are the values: 0 (default)…999 Daylight Saving Time Setup Daylight saving time (DST) setup parameters are found in the Configuration.System.General table.
Other Functions Network Time Synchronization Chapter 8 The PowerMonitor 5000 unit can be set up to synchronize its system clock by using Network Time Synchronization. Network time synchronization clock sources provide better precision and improved coordination between multiple meters. Two different methods of time synchronization are supported, simple network time protocol (SNTP) or precision time protocol (PTP). Applications This applies to all models.
Chapter 8 Other Functions Setup The Network Time Synchronization set-up parameters for SNTP and PTP are found in the Configuration.Communications_Native table.
Other Functions Chapter 8 Table 31 - Time Zone Information Value Offset from GMT Time Zone Name Areas in Time Zone 7 GMT-05:00 Eastern Standard Time Eastern Time (US & Canada) SA Pacific Standard Time Bogota, Lima, Quito US Eastern Standard Time Indiana (East) Atlantic Standard Time Atlantic Time (Canada) Pacific SA Standard Time Santiago SA Western Standard Time Caracas, La Paz 8 GMT-04:00 9 GMT-03:30 Newfoundland Standard Time Newfoundland 10 GMT-03:00 E.
Chapter 8 Other Functions Table 31 - Time Zone Information Value Offset from GMT Time Zone Name 23 GMT+06:00 Central Asia Standard Time Areas in Time Zone Astana, Dhaka N.
Other Functions Chapter 8 Reset (default) Reset performs a warm restart of the power monitor firmware. With Reset selected for unit error action, if a critical error occurs, the power monitor logs the error record to its internal Error Log and then restarts automatically. With Reset selected for the error log full option, the oldest error log record is discarded, and then the power monitor logs the error record to its internal Error Log and then restarts automatically.
Chapter 8 Other Functions Unit_Error_Action These are the selections: 0 = Safe mode 1 = Reset (default) Software_Error_Log_Full_Action 0 = Safe mode 1 = Reset (default) Miscellaneous Commands The following commands relate to the operation of the power monitor at a system level. These commands are found in the Command.System_Registers table. Command_Word_1 Set this command word value to execute the listed action.
Chapter 9 Communication Native Ethernet Communication All PowerMonitor 5000 units are equipped with a native EtherNet/IP 100 BaseT communication port. This section describes EtherNet/IP communication and the available protocols to use for your application. The Ethernet communication port allows communication with your power monitor by using a local-area-network (LAN). The Ethernet port can be used to view the unit’s internal webpage.
Chapter 9 Communication Subnet_Mask_A Subnet_Mask_B Subnet_Mask_C Subnet_Mask_D Ethernet port subnet mask. Gateway_Address_A Gateway_Address_B Gateway_Address_C Gateway_Address_D Ethernet port default gateway address. DNS_Enable Selects DNS Option.
Communication Chapter 9 Setup Setup parameters for the optional DeviceNet port are found in the Configuration.OptionalComm.DNT table. Mac ID Selects the DeviceNet node address. The range is 0…63 (default). Communication Rate Selects the DeviceNet network communication (data) rate, and must be selected to match the remaining devices on the network.
Chapter 9 Communication Electronic Data Sheet (EDS) The EDS file is used to convey device configuration data that is provided by the manufacturer. You can obtain EDS files for the PowerMonitor 5000 unit by downloading the file from the following website. http://www.rockwellautomation.com/rockwellautomation/support/networks/eds.page You can install EDS files on your computer by using the EDS Hardware Installation Tool that comes with RSLinx® Classic software, RSNetWorx™ software, or other tools.
Communication Chapter 9 Data Table Addressing Data tables can be addressed in several ways. Symbolic Addressing Status and metering results data can be addressed by their tag names, similar to the manner in which ControlLogix controller tags are addressed. Symbolic tag addresses are displayed in the power monitor’s web page, and appear in an RSLinx Classic software OPC topic set up for a PowerMonitor 5000 unit. CIP Addressing Addresses are of the form Object:Instance:Attribute.
Chapter 9 Communication Communication Command Summary This section lists the commands supported by each communications network type.
Communication EtherNet/IP Object Model Chapter 9 This section provides the object model for a PowerMonitor 5000 device type on an EtherNet/IP network. The table below indicates the following: • The object classes present in this device • Whether or not the class is required • The number of instances present in each class Object Class List The PowerMonitor 5000 unit supports the following CIP classes.
Chapter 9 Communication This section provides the object model for a PowerMonitor 5000 device type on either a DeviceNet or ControlNet network. The table below indicates the following: • The object classes present in this device • Whether or not the class is required • The number of instances present in each class DeviceNet and ControlNet Object Model Object Class List The PowerMonitor 5000 unit supports the following classes.
Communication Chapter 9 Security Considerations A controller or application does not need to log in to read real-time metering, configuration, and status data from a PowerMonitor 5000 unit, whether security is disabled or enabled. If security is enabled, a controller must log in under an Application account class to perform the following: • Write configuration or commands • Read log data To log in, write the username to the Security.Username table. Within 30 seconds, write the password to the Security.
Chapter 9 Communication Message Type These are the choices: PLC-5 Typed Read SLC Typed Read Source Element Look up the PCCC address of the specific data table address to read. If you are performing a multiple element read, this address specifies the first element in the array. Number of Elements This is the number of elements being read.
Communication Chapter 9 For an explicit message using a DeviceNet or ControlNet network, only the communication path changes, as shown below. Path This field specifies the communication path from the controller to the power monitor. Set-up the path as . Communication Method For PLC-5 and SLC Typed Reads, this always defaults to CIP.
Chapter 9 Communication Number of Elements This is the number of elements being read. These are the values: 1 = Single element write >1 = Multiple element write, number of elements to read including the first element Destination Element Look up the PCCC address (in Appendix A) of the specific data table address to read. If performing a multiple element read, this addresses the first element in the array.
Communication Chapter 9 Class 4 = Assembly object Instance Look up the CIP Instance (in Appendix A) of the specific data table to read or write. This example uses instance 844, the MeteringResults.RealTime_VIF_Power table. Attribute 3 = Data Source Element Used with Write messages, this specifies the controller tag to write to the power monitor. Source Length Used with Write messages, this specifies the length in bytes of the data written to the power monitor.
Chapter 9 Communication Path This field specifies the communication path from the controller to the power monitor. Set-up the path as . Communication Method For CIP Generic messaging, this defaults to CIP.
Communication Chapter 9 Control Block Select an available Integer word. This example uses N7:0. Click Setup Screen. This Controller Data Table Address For a Read message, the controller tag in which to store the power monitor data. For a Write message, the controller tag that stores the value written to the power monitor. Size in Elements This is the number of elements being read or written.
Chapter 9 Communication MultiHop Click Yes, then click the MultiHop tab. Enter the IP Address of the PowerMonitor 5000 unit in the To Address box. SCADA Applications SCADA is short for ‘Supervisory Control and Data Acquisition’, and describes applications in which process data from controllers and other devices is displayed on human-machine interface (HMI) workstations to help system operators monitor operations and make control decisions.
Communication Chapter 9 EtherNet/IP using Ethernet/IP Driver • Create an Ethernet/IP network driver in RSLinx software. • Make selections to browse the local or remote subnet as appropriate. • Use RSWho to verify that RSLinx software is communicating to the PowerMonitor 5000 unit. IMPORTANT The PowerMonitor 5000 unit connects to either the RSLinx Classic Ethernet Devices driver or the Ethernet/IP driver on a single computer but not both simultaneously.
Chapter 9 Communication This creates a new, un-named topic in the left pane. 4. Give the topic a name pertinent to your application. 5. In the right pane, with the Data Source tab selected, browse to the PowerMonitor 5000 unit by using the previously-configured driver. 6. With the topic highlighted in the left pane, and the PowerMonitor 5000 unit highlighted in the right pane, click Apply. 7. Click the Data Collection tab. 8. From the Processor pull-down menu, choose Logix5000.
Communication Chapter 9 Testing the OPC Server by Using Microsoft Excel Software Follow these steps to test the OPC server. 1. From the Edit menu, choose Copy DDE/OPC Link to check out the RSLinx Classic OPC server and the new power monitor topic. 2. In the left pane, browse to Online > MeteringResults > RealTime_VIF_Power and select a tag on the right, then click OK. 3. Open Microsoft Excel software. 4. Right-click a cell and choose Paste Special.
Chapter 9 Communication 5. Click Paste link, and then click OK. The value of the selected tag displays in the cell. You can also check out the OPC topic with the RSLinx OPC Test Client. The figure below shows the difference between symbolic and PCCC addressing. The second item uses symbolic addressing. FactoryTalk Live Data You can also use RSLinx Enterprise software to serve power monitor data to other FactoryTalk applications.
Communication Chapter 9 4. Create a device shortcut that references the new device in the tree and click OK when done. Once the shortcut is created, you can use the Rockwell Live Data Test Client to view PowerMonitor 5000 data. 5. Select the local server and the application area. 6. Select the shortcut, and browse to the Online link. 7. In Appendix A, look up the PCCC address of a data point to monitor.
Chapter 9 Communication 8. Find the address in the list, select it, and click OK. The Test Client displays the data and other properties of the selected tag. This example uses F53:4, V2_N_Volts. Controller Applications: Class 1 Connection This section describes how to set up Class 1 connections with a Logix controller and Studio 5000 Logix Designer application and RSNetWorx software. IMPORTANT Class 1 connections must be inhibited to update the power monitor firmware.
Communication Chapter 9 3. Fill in the power monitor IP address, and the values shown in the figure below for the input, output, and configuration instances. 4. Click OK when finished. The Input instance contains a variety of data types. You need to create controller tags and write controller logic to copy the Input instance data into a usable form. DeviceNet I/O Connection The DeviceNet Class 1 connection sets up implicit communication between the DeviceNet scanner and the PowerMonitor 5000 unit.
Chapter 9 Communication Follow these steps to set up a DeviceNet I/O connection by using RSNetWorx™ for DeviceNet software. 1. Launch RSNetWorx for DeviceNet software. 2. Click Online.
Communication Chapter 9 3. Browse to and choose the DeviceNet network. 4. Accept the prompt to upload the network data. 5. If the PowerMonitor 5000 icon does not appear, upload and install the eds file from the device.
Chapter 9 Communication 6. Select the scanner and upload its configuration. 7. Open the scanner Properties and click the Scanlist tab. 8. Select the PowerMonitor 5000 unit and click the > button to add the unit to the scanlist.
Communication Chapter 9 9. Click the Input tab. Note that the Input mapping is now populated with 60 DWORD elements, obtained from the eds file. The Output mapping is similarly set up with one DWORD. 10. Click OK to accept the changes and download to the scanner. If necessary, place the controller in Program mode. In the Logix controller, the mapped data now appears in the scanner's Local Data tags with a DINT data type.
Chapter 9 Communication ControlNet I/O Connection A ControlNet Class 1 connection sets up the ControlNet scanner in a Logix controller to implicitly read the ScheduledData.Input instance and control outputs without the use of message instructions in logic. The ControlNet connection does not include the power monitor configuration. You can use a web browser, FactoryTalk EnergyMetrix RealTime (RT) software, or other means for power monitor setup.
Communication Chapter 9 6. Complete the New Module setup as shown in the example and click OK when done. The Comm. Format, Input, Output, and Configuration assembly TIP instances and sizes must be entered as shown. Name and optional Description are your choice. Node is the ControlNet address of the power monitor. Click OK when done. 7. In the Module Properties dialog box, click the Connection tab and choose a Requested Packet Interval to suit your application.
Chapter 9 Communication 10. Open RSNetWorx for ControlNet software and click the Online button. 11. Browse to and select the ControlNet network to which the power monitor is connected, and then click OK. 12. Wait until the online browse is complete.
Communication Chapter 9 13. If the PowerMonitor 5000 icon does not appear, upload and install the eds file from the device. 14. Check Edits Enabled, and then click OK. 15. Click the Save icon, then OK to optimize and re-write schedule for all connections. The controller needs to be in Program mode for the download to happen. 16. Put the Logix controller into Run mode and verify the new I/O connection is running. 17. Close out RSNetWorx software, saving the project if desired.
Chapter 9 Communication The following example copies the I.Data tag into a user-defined tag set up with correct data types and symbolic addressing. You must create a destination tag with the appropriate data type. You can obtain user-defined data type (UDT) import files from the Resources tab on the PowerMonitor 5000 product web page. The UDT files for DeviceNet input and output instances also work with ControlNet instances. http://ab.rockwellautomation.
Communication Chapter 9 EDS Add-on Profile Connection (Native EtherNet/IP units only) The PowerMonitor 5000 unit can be configured with an electronic data sheet (EDS) based AOP (add-on profile) in RSLogix 5000 software version 20 or Logix Designer application version 21 or later. You need to register the PowerMonitor 5000 EDS file on the computer on which software project development is done.
Chapter 9 Communication Refer to Appendix A for the content of these data tables. The :C tag is populated with default configuration values. When the connection is opened, the configuration tag is written to the power monitor and over-writes any existing configuration. In most cases this restores the default Metering_Basic and SystemGeneral configuration of the power monitor.
Communication Chapter 9 Refer to Appendix A for the content of the data table. If there is no exclusive owner connection, a listen-only connection returns an error code 16#0119 Connection request error: Module not owned. PowerMonitor 5000 Input Only The PowerMonitor 5000 Input Only connection is similar to the Listen Only connection but does not require an Exclusive Owner connection to exist.
Chapter 9 Communication When you first set up an Input Only connection, the following module-defined controller tag is created: :I, the Input tag, mapped to the ScheduledData.Input table. Refer to Appendix A for the content of the data table. CIP Energy Object The EtherNet/IP communication protocol complies with the Common Industrial Protocol (CIP) and the EtherNet/IP implementation of the CIP specification, published by ODVA.
Communication Chapter 9 CIP Base Energy Object The PowerMonitor 5000 unit supports the following attributes and services of the Base Energy Object, Class Code 0x4E.
Chapter 9 Communication CIP Electrical Energy Object The PowerMonitor 5000 unit supports the following attributes and services of the Electrical Energy Object, Class Code 0x4F.
Communication Chapter 9 Table 36 - Supported Attributes Electrical Energy Object Attribute ID Need in Electrical Energy Object Attribute Name Implementation PM5000 Implementation 36 Optional L1 True Power Factor Supported 37 Optional L2 True Power Factor Supported 38 Optional L3 True Power Factor Supported 39 Optional Three Phase True Power Factor Supported 40 Optional Phase Rotation Supported 41 Required Associated Energy Object Path Supported Table 37 - Supported Services Ener
Chapter 9 Communication The second sample message instruction reads a single value from the electrical energy object. This message calls the Get_Attribute_Single service (service code 0x0E) for the Base Energy Object (Class code 0x4E), to read the Total Energy Odometer, attribute 9. The data is returned in the correct ‘odometer’ format of five integers scaled by powers of 10. In this example, the total energy value is 1,471.371 kWh.
Chapter 10 Maintenance Update the PowerMonitor 5000 Unit Firmware From time to time, firmware updates can be made available for your power monitor. You can also purchase firmware upgrades to add capabilities to your power monitor, for example, promoting an M5 unit to an M6 unit (or M8 unit when released). To load firmware, use the ControlFLASH™ utility. You can download firmware updates from the Rockwell Automation technical support website http://www.rockwellautomation.com/compatibility.
Chapter 10 Maintenance 2. From the Product Search pull-down menu, choose Energy Monitoring. 3. Select the 1426-M5E, series and version to download and respond to the prompts. Your selections appear in the column on the right. 4. Click Find Downloads. Your download selections appear. 5. Click the download button and follow the prompts. 6. After you have downloaded the firmware kit, locate the downloaded ZIP file. 7. Open the ZIP file, and then double-click the ControlFLASH.
Maintenance Upgrading the PowerMonitor 5000 Model and Communication Chapter 10 You can upgrade an M5 model to an M6 model by installing a firmware upgrade kit. Contact your local Rockwell Automation representative or Allen-Bradley distributor to purchase an upgrade. You need to provide the catalog and serial numbers of your existing PowerMonitor 5000 units. The upgrade is furnished with instructions for installation over the native Ethernet, USB, or optional communication ports.
Chapter 10 Maintenance 9. To close the ControlFLASH utility, click Cancel and Yes. TIP 224 If an error message appears that indicates the target device is not in a proper mode to accept an update, then one or more Class 1 connections exist. Refer to the IMPORTANT note above.
Appendix A PowerMonitor 5000 Unit Data Tables The Data Table Summary Index table summarizes all data tables available and their general attributes. Summary of Data Tables Table 38 - Data Table Summary Index Name of Data Table Read M5 M6 ScheduledData.Input X X X X X ScheduledData.Output Write PCCC File Number CIP Instance Number # of Table Parameters Refer to Page 100 65 page 228 X 101 1 page 232 102 43 page 233 NA NA 52 page 238 NA NA 116 page 240 Configuration.
Appendix A PowerMonitor 5000 Unit Data Tables Table 38 - Data Table Summary Index Name of Data Table Read M5 M6 Write PCCC File Number CIP Instance Number # of Table Parameters Refer to Page Security.Username X X X ST29 820 1 page 289 Security.Password X X X ST30 821 1 page 290 Status.General X X X N32 823 55 page 291 Status.Communications X X X N33 824 61 page 292 Status.RunTime X X X N34 825 73 page 293 Status.
PowerMonitor 5000 Unit Data Tables Appendix A Table 38 - Data Table Summary Index Name of Data Table Read LoggingResults.WaveformFileName (M6 model) X LoggingResults.Waveform_Log (M6 model) M5 M6 Write PCCC File Number CIP Instance Number # of Table Parameters Refer to Page X ST78 869 1 page 350 X X F80 871 43 page 351 PowerQuality.RealTime_PowerQuality X X F54 845 56 page 353 PowerQuality.Harmonics_Results (M6 model) X X F69 860 37 page 355 PowerQuality.
Appendix A PowerMonitor 5000 Unit Data Tables These tables detail each specific data table and its associated elements, such as start bytes, size, default value, ranges, and description. Data Tables IMPORTANT The lock symbol designates that the parameter that is marked is not able to be written when the hardware lock switch is in the lock position. ScheduledData.Input Table 39 - Table Properties CIP Assembly Instance 100 No.
PowerMonitor 5000 Unit Data Tables Appendix A Table 40 - ScheduledData.
Appendix A PowerMonitor 5000 Unit Data Tables Table 40 - ScheduledData.Input Data Table Start Byte Size Type Tag Name Description Units Range 48 4 Real V1ToV2Voltage V1 to V2 true RMS voltage V 0…9.999E15 52 4 Real V2ToV3Voltage V2 to V3 true RMS voltage V 0…9.999E15 56 4 Real V3ToV1Voltage V3 to V1 true RMS voltage V 0…9.999E15 60 4 Real AvgVToVVoltage Average of V1_V2, V2_V3 and V3_V1. V 0…9.999E15 64 4 Real I1Current I1 true RMS amps A 0…9.
PowerMonitor 5000 Unit Data Tables Appendix A Table 40 - ScheduledData.Input Data Table Start Byte Size Type Tag Name Description Units Range 204 4 Real Demand_kW The average real power during the last demand period. kW +/- 0.000…9,999,999 208 4 Real Demand_kVAR The average reactive power during the last demand period. kVAR +/- 0.000…9,999,999 212 4 Real Demand_kVA The average apparent power during the last demand period. kVA 0.
Appendix A PowerMonitor 5000 Unit Data Tables ScheduledData.Output Table 41 - Table Properties CIP Instance Number 101 No. of Elements 1 Length in Words 2 Data Type DWORD Data Access Write Only Table 42 - ScheduledData.
PowerMonitor 5000 Unit Data Tables Appendix A Configuration.Instance Table 43 - Table Properties CIP 102 No. of Elements 43 Length in Words 80 Data Type Varies Data Access Read/Write Table 44 - Configuration.Instance Data Table Start Byte Size Type Tag Name Description Units Range 0 1 SINT MeterMode Configures the input wiring for metering.
Appendix A PowerMonitor 5000 Unit Data Tables Table 44 - Configuration.Instance Data Table Start Byte Size Type Tag Name Description Units Range 48 1 SINT RealTimeUpdateRate Selects the update rate for the realtime table and the setpoint calculations.
PowerMonitor 5000 Unit Data Tables Appendix A Table 44 - Configuration.Instance Data Table Start Byte Size Type Tag Name Description Units Range 72 2 INT ForcedDemandSyncDelay When the power monitor is configured for external demand control the unit delays for xxx seconds after the expected control pulse has not been received. The demand period starts over and a record is recorded in the status log 0 = Wait forever 1…900 = Wait this many seconds before starting a new demand period.
Appendix A PowerMonitor 5000 Unit Data Tables Table 44 - Configuration.Instance Data Table Start Byte Size Type Tag Name Description Units Range 100 2 INT R1PulseDuration Set as 50…1000 to indicate the duration of the pulse in milliseconds, or set to 0 for KYZ-style transition output. (Toggle) IMPORTANT: The value for delay is rounded off to the nearest 10 ms internally during this function.
PowerMonitor 5000 Unit Data Tables Appendix A Table 44 - Configuration.Instance Data Table Start Byte Size Type Tag Name Description Units Range 144 1 SINT KYZCommFaultMode The Default output state on communication loss defines the behavior of the output if the power monitor experiences a loss of communication.
Appendix A PowerMonitor 5000 Unit Data Tables Configuration Parameter Object Table Table 45 - Table Properties CIP Class Code 0x0F No. of Parameters 52 Data Type Varies Data Access Read/Write TIP Refer to Table 44 Configuration.Instance Data Table for descriptions of each parameter.
PowerMonitor 5000 Unit Data Tables Appendix A Table 46 - Configuration Parameter Object Table Instance Number Parameter Object Name Type Units Range Default Value 29 Demand_Broadcast_Mode_Select Int16 N/A 0…1 0 30 Demand_Broadcast_Port Int16 N/A 300…400 300 31 KYZ_Solid_State_Output_Parameter Real N/A 0…9 0 32 KYZ_Solid_State_Output_Scale Real N/A 1…100,000 1000 33 KYZ_Pulse_Duration_Setting Real N/A 0 or 50 …1000 250 34 Output_Relay_1_Output_Parameter Real N/A 0…9
Appendix A PowerMonitor 5000 Unit Data Tables Display Parameter Object Table Table 47 - Table Properties CIP Class Code 0x0F No.
PowerMonitor 5000 Unit Data Tables Appendix A Table 48 - Display Parameter Object Table Instance Number Parameter Object Name Type Units Description 84 L1_Disp_PF Real % L1 displacement power factor (fundamental only) 85 L2_Disp_PF Real % L2 displacement power factor (fundamental only) 86 L3_Disp_PF Real % L3 displacement power factor (fundamental only) 87 Avg_Disp_PF Real % Average displacement power factor (fundamental only) 88 V1_Crest_Factor Real CF V1 crest factor 89 V2
Appendix A PowerMonitor 5000 Unit Data Tables Table 48 - Display Parameter Object Table Instance Number Parameter Object Name Type Units Description 123 Status_1_Count_xM Real xM Status 1 Count times 1,000,000 124 Status_1_Count_x1 Real x1 Status 1 count times 1 125 Status_2_Count_xM Real xM Status 2 Count times 1,000,000 126 Status_2_Count_x1 Real x1 Status 2 count times 1 127 Status_3_Count_xM Real xM Status 3 Count times 1,000,000 128 Status_3_Count_x1 Real x1 Status 3
PowerMonitor 5000 Unit Data Tables Appendix A Table 48 - Display Parameter Object Table Instance Number Parameter Object Name Type Units Description 166 Metering_Status Int16 N/A Metering Conditions Status 167 Over_Range_Information Int16 N/A Indicates which input is over range 168 PowerQuality_Status Int16 N/A Power Quality Conditions Status 169 Logs_Status Int16 N/A Logs Condition Status Configuration.
Appendix A PowerMonitor 5000 Unit Data Tables Configuration.Logging Table 51 - Table Properties CIP Instance Number 801 PCCC File Number N10 No. of Elements 40 Length in Words 40 Data Type Int16 Data Access Read/Write Table 52 - Configuration.Logging Data Table Element Type Number Tag Name Description Default Range 0 Int16 Energy_Log_Interval Selects how often a record is logged (minutes). A value of 0 disables periodic logging of records.
PowerMonitor 5000 Unit Data Tables Appendix A Table 52 - Configuration.Logging Data Table Element Type Number Tag Name Description Default Range 6 Int16 MID_Peak_PM_Hours This bit map selects any p.m. hours that are designated as MID Peak. Bit0 = 12 p.m. to 1 p.m. Bit1 = 1 p.m. to 2 p.m. Bit2 = 2 p.m. to 3 p.m. Bit 3 = 3 p.m. to 4 p.m. … Bit11 = 11 p.m. to 12 p.m. Example: The hours from 3 p.m. to 7 p.m. is designated as Bit 3 through Bit 6 = 120d.
Appendix A PowerMonitor 5000 Unit Data Tables Configuration.Metering.Basic Table 53 - Table Properties CIP Instance Number 802 PCCC File Number F11 No. of Elements 33 Length in Words 66 Data Type Real Data Access Read/Write Table 54 - Configuration.Metering.Basic Data Table Element Type Number Tag Name Description Default Range 0 Real Metering_Mode Configures the input wiring for metering.
PowerMonitor 5000 Unit Data Tables Appendix A Table 54 - Configuration.Metering.Basic Data Table Element Type Number Tag Name Description Default Range 13 Real Demand_Period_Length (Minutes) Specifies the desired period for demand calculations. When set to 0 there is no projected demand calculations. If the internal timer is selected a setting of 0 turns the demand function off. 15 0…99 14 Real Number_Demand_Periods Specifies the number of demand periods to average for demand measurement.
Appendix A PowerMonitor 5000 Unit Data Tables Configuration.System.General Table 55 - Table Properties CIP Instance Number 803 PCCC File Number F12 No. of Elements 50 Length in Words 100 Data Type Real Data Access Read/Write Table 56 - Configuration.System.
PowerMonitor 5000 Unit Data Tables Appendix A Table 56 - Configuration.System.General Data Table Element Type Number Tag Name Description Default Range 7 Real KYZ_Solid_State_Output_Scale The KYZ output parameter divided by the scale is the output pulse rate. Example: Wh is selected for the parameter and 1,000 is the scale value. The output is pulsed every kWh.
Appendix A PowerMonitor 5000 Unit Data Tables Table 56 - Configuration.System.General Data Table Element Type Number Tag Name Description Default Range 18 Real Status_Input_1_Input_Scale When a status pulse is received the count is increased by the scale factor. (Input pulse * input scale) added to total status count. 1 1… 1,000,000 19 Real Status_Input_2_Input_Scale When a status pulse is received the count is increased by the scale factor.
PowerMonitor 5000 Unit Data Tables Appendix A Configuration.Communications_Native Table 57 - Table Properties CIP Instance Number 804 PCCC File Number N13 No. of Elements 70 Length in Words 70 Data Type Int16 Data Access Read/Write Table 58 - Configuration.
Appendix A PowerMonitor 5000 Unit Data Tables Table 58 - Configuration.
PowerMonitor 5000 Unit Data Tables Appendix A Configuration.Network.Text Table 59 - Table Properties CIP Instance Number 805 PCCC File Number ST14 No. of Elements 5 Length in Bytes 208 Data Type String Data Access Read/Write Table 60 - Configuration.Network.
Appendix A PowerMonitor 5000 Unit Data Tables Configuration.Setpoints_1_5 Table 61 - Table Properties CIP Instance Number 807 PCCC File Number F16 No. of Elements 50 Length in Words 100 Data Type Real Data Access Read/Write Table 62 - Configuration.Setpoints_1_5 Data Table Element Number Type Tag Name Description Default Range 0 Real Parameter Selection 1 Selection of the input parameter from the Setpoint Parameter Selection List.
PowerMonitor 5000 Unit Data Tables Appendix A Table 62 - Configuration.Setpoints_1_5 Data Table Element Number Type Tag Name Description Default Range 13 Real Hysteresis 2 The value in magnitude or percent of reference at which the output action is deasserted. Example: A less than condition deasserts at (threshold + hysteresis), a greater than condition deasserts at (threshold - hysteresis).
Appendix A PowerMonitor 5000 Unit Data Tables Table 62 - Configuration.Setpoints_1_5 Data Table Element Number Type Tag Name Description Default Range 32 Real Parameter Selection 5 Selection of the input parameter from the Setpoint Parameter Selection List. 0 0…105 33 Real Input Reference Selection 5 Selects the type of input conditioning for non boolean parameters.
PowerMonitor 5000 Unit Data Tables Appendix A Configuration.Setpoints_6_10 Table 63 - Table Properties CIP Instance Number 808 PCCC File Number F17 No. of Elements 50 Length in Words 100 Data Type Real Data Access Read/Write Table 64 - Configuration.Setpoints_6_10 Data Table Element Type Number Tag Name Description Default Range 0 Real Parameter Selection 6 Selection of the input parameter from the Setpoint Parameter Selection List.
Appendix A PowerMonitor 5000 Unit Data Tables Table 64 - Configuration.Setpoints_6_10 Data Table Element Type Number Tag Name Description Default Range 13 Real Hysteresis 7 The value in magnitude or percent of reference at which the output action is deasserted. Example: A less than condition deasserts at (threshold + hysteresis), a greater than condition deasserts at (threshold - hysteresis).
PowerMonitor 5000 Unit Data Tables Appendix A Table 64 - Configuration.Setpoints_6_10 Data Table Element Type Number Tag Name Description Default Range 32 Real Parameter Selection 10 Selection of the input parameter from the Setpoint Parameter Selection List. 0 0…105 33 Real Input Reference Selection 10 Selects the type of input conditioning for non boolean parameters.
Appendix A PowerMonitor 5000 Unit Data Tables Configuration.Setpoints_11_15 (M6 model) Table 65 - Table Properties CIP Instance Number 809 PCCC File Number F18 No. of Elements 50 Length in Words 100 Data Type Real Data Access Read/Write Table 66 - Configuration.Setpoints_11_15 Data Table Element Type Number Tag Name Description Default Range 0 Real Parameter Selection 115 Selection of the input parameter from the Setpoint Parameter Selection List.
PowerMonitor 5000 Unit Data Tables Appendix A Table 66 - Configuration.Setpoints_11_15 Data Table Element Type Number Tag Name Description Default Range 13 Real Hysteresis 12 The value in magnitude or percent of reference at which the output action is deasserted. Example: A less than condition deasserts at (threshold + hysteresis), a greater than condition deasserts at (threshold - hysteresis).
Appendix A PowerMonitor 5000 Unit Data Tables Table 66 - Configuration.Setpoints_11_15 Data Table Element Type Number Tag Name Description Default Range 32 Real Parameter Selection 15 Selection of the input parameter from the Setpoint Parameter Selection List. 0 0…105 33 Real Input Reference Selection 15 Selects the type of input conditioning for non boolean parameters.
PowerMonitor 5000 Unit Data Tables Appendix A Configuration.Setpoints_16_20 (M6 model) Table 67 - Table Properties CIP Instance Number 810 PCCC File Number F19 No. of Elements 50 Length in Words 100 Data Type Real Data Access Read/Write Table 68 - Configuration.Setpoints_16_20 Data Table Element Type Number Tag Name Description Default Range 0 Real Parameter Selection 16 Selection of the input parameter from the Simple Setpoint Parameter List.
Appendix A PowerMonitor 5000 Unit Data Tables Table 68 - Configuration.Setpoints_16_20 Data Table Element Type Number Tag Name Description Default Range 13 Real Hysteresis 17 The value in magnitude or percent of reference at which the output action is deasserted. Example: A less than condition deasserts at (threshold + hysteresis), a greater than condition deasserts at (threshold - hysteresis).
PowerMonitor 5000 Unit Data Tables Appendix A Table 68 - Configuration.Setpoints_16_20 Data Table Element Type Number Tag Name Description Default Range 32 Real Parameter Selection 20 Selection of the input parameter from the Setpoint Parameter Selection List. 0 0…105 33 Real Input Reference Selection 20 Selects the type of input conditioning for non boolean parameters.
Appendix A PowerMonitor 5000 Unit Data Tables Configuration.Setpoint_Logic (M6 Model) Table 69 - Table Properties CIP Instance Number 811 PCCC File Number N20 No. of Elements 100 Length in Words 100 Data Type Int16 Data Access Read/Write Table 70 - Configuration.
PowerMonitor 5000 Unit Data Tables Appendix A Table 70 - Configuration.Setpoint_Logic Data Table Element Type Number Tag Name Description Default Range 5 Int16 Logic Level 1 Gate 2 Function Selects the logic type 0 = disabled 1 = AND 2 = NAND 3 = OR 4 = NOR 5 = XOR 6 = XNOR IMPORTANT: XOR and XNOR use Inputs 1 and 2 only. 0 0…6 6 Int16 L1_G2 Input 1 Selects the first input parameter for the gate. Each gate has four inputs.
Appendix A PowerMonitor 5000 Unit Data Tables Table 70 - Configuration.Setpoint_Logic Data Table Element Type Number Tag Name Description Default Range 11 Int16 L1_G3 Input 1 Selects the first input parameter for the gate. Each gate has four inputs. 0 = Disabled 1 = Setpoint 1 2 = Setpoint 2 3 = Setpoint 3 … 20 = Setpoint 20 IMPORTANT: Negative numbers invert the input. 0 -20…20 12 Int16 L1_G3 Input 2 Selects the second input parameter for the gate. Each gate has four inputs.
PowerMonitor 5000 Unit Data Tables Appendix A Table 70 - Configuration.Setpoint_Logic Data Table Element Type Number Tag Name Description Default Range 17 Int16 L1_G4 Input 2 Selects the second input parameter for the gate. Each gate has four inputs. 0 = Disabled 1 = Setpoint 1 2 = Setpoint 2 3 = Setpoint 3 … 20 = Setpoint 20 IMPORTANT: Negative numbers invert the input. 0 -20…20 18 Int16 L1_G4 Input 3 Selects the third input parameter for the gate. Each gate has four inputs.
Appendix A PowerMonitor 5000 Unit Data Tables Table 70 - Configuration.Setpoint_Logic Data Table Element Type Number Tag Name Description Default Range 23 Int16 L1_G5 Input 3 Selects the third input parameter for the gate. Each gate has four inputs. 0 = Disabled 1 = Setpoint 1 2 = Setpoint 2 3 = Setpoint 3 … 20 = Setpoint 20 IMPORTANT: Negative numbers invert the input. 0 -20…20 24 Int16 L1_G5 Input 4 Selects the fourth input parameter for the gate. Each gate has four inputs.
PowerMonitor 5000 Unit Data Tables Appendix A Table 70 - Configuration.Setpoint_Logic Data Table Element Type Number Tag Name Description Default Range 29 Int16 L1_G6 Input 4 Selects the fourth input parameter for the gate. Each gate has four inputs. 0 = Disabled 1 = Setpoint 1 2 = Setpoint 2 3 = Setpoint 3 … 20 = Setpoint 20 IMPORTANT: Negative numbers invert the input.
Appendix A PowerMonitor 5000 Unit Data Tables Table 70 - Configuration.Setpoint_Logic Data Table Element Type Number Tag Name Description Default Range 35 Int16 Logic Level 1 Gate 8 Function Selects the logic type 0 = disabled 1 = AND 2 = NAND 3 = OR 4 = NOR 5 = XOR 6 = XNOR IMPORTANT: XOR and XNOR use Inputs 1 and 2 only. 0 0…6 36 Int16 L1_G8 Input 1 Selects the first input parameter for the gate. Each gate has four inputs.
PowerMonitor 5000 Unit Data Tables Appendix A Table 70 - Configuration.Setpoint_Logic Data Table Element Type Number Tag Name Description Default Range 41 Int16 L1_G9 Input 1 Selects the first input parameter for the gate. Each gate has four inputs. 0 = Disabled 1 = Setpoint 1 2 = Setpoint 2 3 = Setpoint 3 … 20 = Setpoint 20 IMPORTANT: Negative numbers invert the input. 0 -20…20 42 Int16 L1_G9 Input 2 Selects the second input parameter for the gate. Each gate has four inputs.
Appendix A PowerMonitor 5000 Unit Data Tables Table 70 - Configuration.Setpoint_Logic Data Table Element Type Number Tag Name Description Default Range 47 Int16 L1_G10 Input 2 Selects the second input parameter for the gate. Each gate has four inputs. 0 = Disabled 1 = Setpoint 1 2 = Setpoint 2 3 = Setpoint 3 … 20 = Setpoint 20 IMPORTANT: Negative numbers invert the input. 0 -20…20 48 Int16 L1_G10 Input 3 Selects the third input parameter for the gate. Each gate has four inputs.
PowerMonitor 5000 Unit Data Tables Appendix A Configuration.Setpoint_Outputs Table 71 - Table Properties CIP Instance Number 812 PCCC File Number N21 No. of Elements 100 Length in Words 100 Data Type Int16 Data Access Read/Write Table 72 - Configuration.Setpoint_Outputs Data Table Element Number Type Tag Name Description Default Range 0 Int16 Setpoint Output 1 Input Source Selects the source for output. Setpoint or gate output state.
Appendix A PowerMonitor 5000 Unit Data Tables Table 72 - Configuration.Setpoint_Outputs Data Table Element Number Type Tag Name Description Default Range 8 Int16 Setpoint Output 5 Input Source Selects the source for output. Setpoint or gate output state. 0 = No source 1 = Setpoint1 2 = Setpoint 2… 20 = Setpoint 20 21 = Level1_G1 ... 30 = Level1_G10 5 0…10 (M5) 0…30 (M6) 9 Int16 Setpoint Output 5 Action Selects the output action to perform when setpoint is asserted.
PowerMonitor 5000 Unit Data Tables Appendix A Table 72 - Configuration.Setpoint_Outputs Data Table Element Number Type Tag Name Description Default Range 18 Int16 Setpoint Output 10 Input Source Selects the source for output. Setpoint or gate output state. 0 = No source 1 = Setpoint1 2 = Setpoint 2… 20 = Setpoint 20 21 = Level1_G1 ... 30 = Level1_G10 10 0…10 (M5) 0…30 (M6) 19 Int16 Setpoint Output 10 Action Selects the output action to perform when setpoint is asserted.
Appendix A PowerMonitor 5000 Unit Data Tables Table 72 - Configuration.Setpoint_Outputs Data Table Element Number Type Tag Name Description 29 Int16 Setpoint Output 15 Action Selects the output action to perform when setpoint is asserted. See the Setpoint Output Action List. 0 0…30 (M6) 30 Int16 Setpoint Output 16 Input Source Selects the source for output. Setpoint or gate output state. 0 = No source 1 = Setpoint 1 2 = Setpoint 2… 20 = Setpoint 20 21 = Level1_G1 ...
PowerMonitor 5000 Unit Data Tables Appendix A Configuration.Data_Log Table 73 - Table Properties CIP Instance Number 813 PCCC File Number N22 No. of Elements 34 Length in Words 34 Data Type Int16 Data Access Read/Write Table 74 - Configuration.Data_Log Data Table Element Type Number Tag Name (default tag name) Description Default Range 0 Int16 Data_Logging_Interval Logging Interval in seconds.
Appendix A PowerMonitor 5000 Unit Data Tables Table 74 - Configuration.Data_Log Data Table Element Type Number Tag Name (default tag name) Description Default Range 16 Int16 DataLog_Parameter_15 (Avg_IEC_THD_V_V_%) Selection of parameter or default to be logged in the data log. 72 0…88 (M5) 1…184 (M6) 17 Int16 DataLog_Parameter_16 (Avg_IEC_THD_I_%) Selection of parameter or default to be logged in the data log.
PowerMonitor 5000 Unit Data Tables Appendix A Configuration.Log_Read Table 75 - Table Properties CIP Instance Number 814 PCCC File Number N23 No. of Elements 15 Length in Words 15 Data Type Int16 Data Access Read/Write Table 76 - Configuration.Log_Read Data Table Element Number Type Tag Name Description Default Range 0 Int16 Selected Log Selects the log that information is returned from.
Appendix A PowerMonitor 5000 Unit Data Tables Configuration.PowerQuality Table 77 - Table Properties CIP Instance Number 815 PCCC File Number F24 No. of Elements 50 Length in Words 100 Data Type Real Data Access Read/Write Table 78 - Configuration.PowerQuality Data Table Element Type Number Tag Name Description Default Range 0 Real Sag1_Trip_Point_% The percent of Nominal System Voltage that creates a level 1 sag condition. 90 0.00…100.
PowerMonitor 5000 Unit Data Tables Appendix A Table 78 - Configuration.PowerQuality Data Table Element Type Number Tag Name Description Default Range 23 Real IEEE1159_Voltage_Imbalance_Limit_% The percent of voltage Imbalance to create an imbalance event 3 1.00…10.00 24 Real IEEE1159_Current_Imbalance_Limit_% The percent of current Imbalance to create an imbalance event 25 1.00…50.
Appendix A PowerMonitor 5000 Unit Data Tables Configuration.OptionalComm.DNT Table 79 - Table Properties CIP Instance Number 816 PCCC File Number N25 No. of Elements 30 Length in Words 30 Data Type Int16 Data Access Read/Write Table 80 - Configuration.OptionalComm.DNT Data Table Element Number Type Tag Name Description Default Range 0 Int16 DeviceNet_Address DeviceNet optional card device address 63 0…63 1 Int16 DeviceNet_Baudrate DeviceNet optional card communication rate.
PowerMonitor 5000 Unit Data Tables Appendix A Configuration.OptionalComm.CNT Table 81 - Table Properties (instance and file #s the same as DNT because only 1 can be present) CIP Instance Number 816 PCCC File Number N25 No. of Elements 30 Length in Words 30 Data Type Int16 Data Access Read/Write Table 82 - Configuration.OptionalComm.CNT Data Table Element Number Type Tag Name Description Default Range 0 Int16 ControlNet_Address ControlNet optional card device address.
Appendix A PowerMonitor 5000 Unit Data Tables Configuration.EnergyLogFile Table 85 - Table Properties CIP Instance Number 818 PCCC File Number ST27 No. of Elements 1 Length in Words 32 Data Type String Data Access Write Table 86 - Configuration.EnergyLogFile Data Table Element Number Type Tag Name Description Default Range 0 String Energy_Log_File_ Name A single entry table for a 64 character Filename entry 0 64 bytes Configuration.
PowerMonitor 5000 Unit Data Tables Appendix A Configuration.TriggerSetpointInfoFile (M6 model) Table 89 - Table Properties CIP Instance Number 865 PCCC File Number ST74 No. of Elements 1 Length in Words 32 Data Type String Data Access Write Only Table 90 - Configuration.TriggerSetpointInfoFile Data Table Element Type Number Tag Name Description Default Range 0 Trigger_Setpoio nt_Log_File A single entry table for a 64 character Filename entry 0 64 bytes String Configuration.
Appendix A PowerMonitor 5000 Unit Data Tables Configuration.Harmonics_Optional_Read Table 93 - Table Properties CIP Instance Number 819 PCCC File Number N28 No. of Elements 15 Length in Words 15 Data Type Int16 Data Access Write Table 94 - Configuration.Harmonics_Optional_Read Data Table Element Number Type Tag Name Description Default Range 0 Int16 Channel Selection Selects the channel associated with the data returned in a subsequent read of Table PowerQuality.Harmonics_Results.
PowerMonitor 5000 Unit Data Tables Appendix A Configuration.WaveformFileName (M6 model) Table 95 - Table Properties CIP Instance Number 870 PCCC File Number ST79 No. of Elements 1 Length in Words 32 Data Type String Data Access Write Only Table 96 - Configuration.
Appendix A PowerMonitor 5000 Unit Data Tables Security.Password Table 99 - Table Properties CIP Instance Number 821 PCCC File Number ST30 No. of Elements 1 Length in Words 16 Data Type String Data Access Write Only Table 100 - Security.
PowerMonitor 5000 Unit Data Tables Appendix A Status.General Table 101 - Table Properties CIP Instance Number 823 PCCC File Number N32 No. of Elements 55 Length in Words 55 Data Type Int16 Data Access Read Only Table 102 - Status.General Data Table Element Number Type Tag Name Description Range 0 Int16 Bulletin_Number 1426 0 or 1426 1 Int16 Device_Class Describes the product device type.
Appendix A PowerMonitor 5000 Unit Data Tables Status.Communications Table 103 - Table Properties CIP Instance Number 824 PCCC File Number N33 No. of Elements 61 Length in Words 61 Data Type Int16 Data Access Read Only Table 104 - Status.
PowerMonitor 5000 Unit Data Tables Appendix A Status.RunTime Table 105 - Table Properties CIP Instance Number 825 PCCC File Number N34 No. of Elements 86 Length in Words 86 Data Type Int16 Data Access Read Only Table 106 - Status.
Appendix A PowerMonitor 5000 Unit Data Tables Table 106 - Status.
PowerMonitor 5000 Unit Data Tables Appendix A Table 106 - Status.
Appendix A PowerMonitor 5000 Unit Data Tables Status.DiscreteIO Table 107 - Table Properties CIP Instance Number 826 PCCC File Number N35 No. of Elements 112 Length in Words 112 Data Type Int16 Data Access Read Only Table 108 - Status.
PowerMonitor 5000 Unit Data Tables Appendix A Status.Wiring_Diagnostics Table 109 - Table Properties CIP Instance Number 829 PCCC File Number F38 No. of Elements 33 Length in Words 66 Data Type Real Data Access Read Only Table 110 - Status.Wiring_Diagnostics Data Table Element Number Type Tag Name Description Range 0 Real Command_Status This is the wiring diagnostics command status.
Appendix A PowerMonitor 5000 Unit Data Tables Table 110 - Status.Wiring_Diagnostics Data Table Element Number Type Tag Name Description Range 5 Real Range1_Current_Input_Inverted Reports on all three phases. -1 = Test not run 0 = Test passed 1 = Phase 1 inverted 2 = Phase 2 inverted 3 = Phase 3 inverted 12 = Phase 1 and 2 inverted 13 = Phase 1 and 3 inverted 23 = Phase 2 and 3 inverted 123 = All phases inverted -1…123 6 Real Range1_Voltage_Rotation Reports on all three phases.
PowerMonitor 5000 Unit Data Tables Appendix A Table 110 - Status.Wiring_Diagnostics Data Table Element Number Type Tag Name Description Range 12 Real Range2_Current_Rotation Reports on all three phases. The reported sequence represents each phase. 1…321 designating phase and rotation. Example: 123 = Phase 1 then phase 2 then phase 3 -1 = Test not run 4 = Invalid Rotation 5 = Out of range -1…321 13 Real Range3_L52_L95_Status This is the pass fail status for Range 1 diagnostics.
Appendix A PowerMonitor 5000 Unit Data Tables Table 110 - Status.Wiring_Diagnostics Data Table Element Number Type Tag Name Description Range 27 Real Current_Phase_2_Magnitude Shows the present magnitude of this phase. 0…9,999,999 28 Real Current_Phase_3_Angle Shows the present phase angle of this channel. 0…359.99 29 Real Current_Phase_3_Magnitude Shows the present magnitude of this phase. 0…9,999,999 30…32 Real Reserved Reserved for future use. 0 Status.
PowerMonitor 5000 Unit Data Tables Appendix A Status.InformationTable Table 113 - Table Properties CIP Instance Number 831 PCCC File Number ST40 No. of Elements 10 Length in Words 112 Data Type String Data Access Read Only Table 114 - Status.InformationTable Data Table Element Number Size Bytes Type Tag Name Description Range 0 20 String Catalog Number The unit catalog number example. 0…255 1 20 String Serial Number The serial number for warranty information.
Appendix A PowerMonitor 5000 Unit Data Tables Status.Alarms Table 115 - Table Properties CIP Instance Number 832 PCCC File Number N41 No. of Elements 32 Length in Words 32 Data Type Int16 Data Access Read Only Table 116 - Status.
PowerMonitor 5000 Unit Data Tables Appendix A Table 116 - Status.
Appendix A PowerMonitor 5000 Unit Data Tables Table 116 - Status.
PowerMonitor 5000 Unit Data Tables Appendix A Table 116 - Status.Alarms Data Table Element Number Type Tag Name Description Range 13 Int16 IEEE1159_Current_THD_Condition IEEE1159 Current THD Condition 0…65535 Bit 0 IEEE1159_Current_THD_Condition_ I1 1 = A THD exceed limitation is detected on I1 0…1 Bit 1 IEEE1159_Current_THD_Condition_ I2 1 = A THD exceed limitation is detected on I2 0…1 Bit 2 IEEE1159_Current_THD_Condition_ I3 1 = A THD exceed limitation is detected on I3 0…1 Bit 3.
Appendix A PowerMonitor 5000 Unit Data Tables Table 116 - Status.
PowerMonitor 5000 Unit Data Tables Appendix A Table 116 - Status.
Appendix A PowerMonitor 5000 Unit Data Tables Table 116 - Status.
PowerMonitor 5000 Unit Data Tables Appendix A Status.OptionalComm Table 117 - Table Properties CIP Instance Number 835 PCCC File Number N44 No. of Elements 30 Length in Words 30 Data Type Int16 Data Access Read Only Table 118 - Status.
Appendix A PowerMonitor 5000 Unit Data Tables Table 118 - Status.
PowerMonitor 5000 Unit Data Tables Appendix A Status.Wiring_Corrections Table 119 - Table Properties CIP Instance Number 834 PCCC File Number N43 No. of Elements 14 Length in Words 14 Data Type Int16 Data Access Read Only Table 120 - Status.
Appendix A PowerMonitor 5000 Unit Data Tables Table 120 - Status.Wiring_Corrections Data Table Element Number Type Tag Name Description Default Range 5 Int16 Input_I2_Mapping This parameter logically maps a physical current channel to I2. 1 = I1 2 = I2 3 = I3 -1 = I1 inverted -2 = I2 inverted -3 = I3 inverted 2 -3…-1 1…3 6 Int16 Input_I3_Mapping This parameter logically maps a physical current channel to I3.
PowerMonitor 5000 Unit Data Tables Appendix A Status.IEEE1588 (M6 model) Table 121 - Table Properties CIP Instance Number 873 PCCC File Number N82 No. of Elements 49 Length in Words 49 Data Type INT16 Data Access Read Only Table 122 - Status.IEEE1588 Data Table (M6 model) Element Type Number Tag Name Description Range 0 Int16 IEEE1588_Version IEEE1588 Version 2 2 1 Int16 PTPEnable PTPEnable specifies the enable status for the Precision Time Protocol on the device.
Appendix A PowerMonitor 5000 Unit Data Tables Table 122 - Status.IEEE1588 Data Table (M6 model) Element Type Number Tag Name Description Range 19 Int16 MeanPathDelayToMaster_A MeanPathDelayToMaster specifies the average path delay between the local clock and master clock in nanoseconds. (Bit 0 to bit 15) 0…0xffff 20 Int16 MeanPathDelayToMaster_B MeanPathDelayToMaster specifies the average path delay between the local clock and master clock in nanoseconds.
PowerMonitor 5000 Unit Data Tables Appendix A Statistics.Setpoint_Output Table 123 - Table Properties CIP Instance Number 827 PCCC File Number N36 No. of Elements 112 Length in Words 112 Data Type Int16 Data Access Read Only Table 124 - Statistics.Setpoint_Output Data Table Element Number Type Tag Name Description Units Range 0 Int16 Setpoint 1 Seconds Accumulator Time accumulator counter for seconds part of total accumulated time.
Appendix A PowerMonitor 5000 Unit Data Tables Table 124 - Statistics.Setpoint_Output Data Table Element Number Type Tag Name Description 18 Int16 Setpoint 4 Transitions to Active x1 The number of actuations for setpoint times 1. 0…999 19 Int16 Setpoint 4 Transitions to Active x1000 The number of actuations for setpoint times 1000. 0…9999 20 Int16 Setpoint 5 Seconds Accumulator Time accumulator counter for seconds part of total accumulated time.
PowerMonitor 5000 Unit Data Tables Appendix A Table 124 - Statistics.Setpoint_Output Data Table Element Number Type Tag Name Description 43 Int16 Setpoint 9 Transitions to Active x1 Time accumulator counter for total hours of accumulated time. 0…999 44 Int16 Setpoint 9 Transitions to Active x1000 The number of actuations for setpoint times 1000. 0…9999 45 Int16 Setpoint 10 Seconds Accumulator Time accumulator counter for seconds part of total accumulated time.
Appendix A PowerMonitor 5000 Unit Data Tables Table 124 - Statistics.Setpoint_Output Data Table Element Number Type Tag Name Description Units Range 65 Int16 Setpoint 14 Seconds Accumulator Time accumulator counter for seconds part of total accumulated time. Sec 0…999 66 Int16 Setpoint 14 Minutes Accumulator Time accumulator counter for minutes part of total accumulated time. Min 0…59 67 Int16 Setpoint 14 Hours Accumulator Time accumulator counter for total hours of accumulated time.
PowerMonitor 5000 Unit Data Tables Appendix A Table 124 - Statistics.Setpoint_Output Data Table Element Number Type Tag Name Description Units Range 87 Int16 Setpoint 18 Hours Accumulator Time accumulator counter for total hours of accumulated time. Hr 0…9999 88 Int16 Setpoint 18 Transitions to Active x1 The number of actuations for setpoint times 1 x1 0…999 89 Int16 Setpoint 18 Transitions to Active x1000 The number of actuations for setpoint times 1000.
Appendix A PowerMonitor 5000 Unit Data Tables Statistics.Logging Table 125 - Table Properties CIP Instance Number 833 PCCC File Number N42 No. of Elements 20 Length in Words 20 Data Type Int16 Data Access Read Only Table 126 - Statistics.Logging Data Table Element Number Type Tag Name Description Range 0 Int16 Number of Unit Event Log Records On a read of this table the value of this parameter is the number of Unit Event Records available.
PowerMonitor 5000 Unit Data Tables Appendix A Statistics.Setpoint_Logic (M6 model) Table 127 - Table Properties CIP Instance Number 828 PCCC File Number N37 No. of Elements 112 Length in Words 112 Data Type Int16 Data Access Read Only Table 128 - Statistics.Setpoint_Logic Data Table Element Type Number Tag Name Description Units Range 0 Int16 Level1 Gate1 Seconds Accumulator Time accumulator counter for seconds part of total accumulated time.
Appendix A PowerMonitor 5000 Unit Data Tables Table 128 - Statistics.Setpoint_Logic Data Table Element Type Number Tag Name Description Units Range 18 Int16 Level1 Gate4 Transitions to Active x1 The number of actuations for setpoint times 1 x1 0…999 19 Int16 Level1 Gate4 Transitions to Active x1000 The number of actuations for setpoint times 1000. x1000 0…9999 20 Int16 Level1 Gate5 Seconds Accumulator Time accumulator counter for seconds part of total accumulated time.
PowerMonitor 5000 Unit Data Tables Appendix A Table 128 - Statistics.Setpoint_Logic Data Table Element Type Number Tag Name Description Units Range 43 Int16 Level1 Gate9 Transitions to Active x1 The number of actuations for setpoint times 1 x1 0…999 44 Int16 Level1 Gate9 Transitions to Active x1000 The number of actuations for setpoint times 1000. x1000 0…9999 45 Int16 Level1 Gate10 Seconds Accumulator Time accumulator counter for seconds part of total accumulated time.
Appendix A PowerMonitor 5000 Unit Data Tables Command.System_Registers Table 129 - Table Properties CIP Instance Number 838 PCCC File Number F47 No. of Elements 45 Length in Words 90 Data Type Real Data Access Write Only Table 130 - Command.System_Registers Data Table Element Number Type Tag Name Description Default Range 0 Real Command Word 1 These commands can be sent to the power monitor.
PowerMonitor 5000 Unit Data Tables Appendix A Table 130 - Command.
Appendix A PowerMonitor 5000 Unit Data Tables Command.Controller_Interface Table 131 - Table Properties CIP Instance Number 839 PCCC File Number N48 No. of Elements 16 Length in Words 16 Data Type Int16 Data Access Write Only Table 132 - Command.Controller_Interface Data Table Element Number Type Tag Name Description Default Range 0 Int16 Controller_Command_Word Bit 0 = When this bit is written to the power monitor it signals the end of the demand period.
PowerMonitor 5000 Unit Data Tables Appendix A Command.Wiring_Corrections Table 133 - Table Properties CIP Instance Number 840 PCCC File Number N49 No. of Elements 14 Length in Words 14 Data Type Int16 Data Access Write Only Table 134 - Command.
Appendix A PowerMonitor 5000 Unit Data Tables Table 134 - Command.Wiring_Corrections Data Table Element Number Type Tag Name Description Default Range 5 Int16 Input_I2_Mapping This parameter logically maps a physical current channel to I2. 1 = I1 2 = I2 3 = I3 -1 = I1 inverted -2 = I2 inverted -3 = I3 inverted 2 -3… -1 1…3 6 Int16 Input_I3_Mapping This parameter logically maps a physical current channel to I3.
PowerMonitor 5000 Unit Data Tables Appendix A MeteringResults.RealTime_VIF_Power Table 135 - Table Properties CIP Instance Number 844 PCCC File Number F53 No. of Elements 56 Length in Words 112 Data Type Real Data Access Read Only Table 136 - MeteringResults.
Appendix A PowerMonitor 5000 Unit Data Tables Table 136 - MeteringResults.RealTime_VIF_Power Data Table Element Number Type Tag Name Description Units Range 29 Real L3_kVA L3 apparent power kVA 0…9.999E15 30 Real Total_kVA Total apparent power kVA 0…9.999E15 31 Real L1_True_PF_% L1 true power factor (full bandwidth) % 0.00…100.00 32 Real L2_True_PF_% L2 true power factor (full bandwidth) % 0.00…100.00 33 Real L3_True_PF_% L3 true power factor (full bandwidth) % 0.00…100.
PowerMonitor 5000 Unit Data Tables Appendix A MeteringResults.Energy_Demand Table 137 - Table Properties CIP Instance Number 846 PCCC File Number F55 No. of Elements 56 Length in Words 112 Data Type Real Data Access Read Only Table 138 - MeteringResults.
Appendix A PowerMonitor 5000 Unit Data Tables Table 138 - MeteringResults.Energy_Demand Data Table Element Number Type Tag Name Description Units Range 29 Real Projected_kW_Demand The projected total real power for the current demand period kW ±0.000…9,999,999 30 Real Projected_kVAR_Demand The projected total reactive power for the current demand period kVAR ±0.000…9,999,999 31 Real Projected_kVA_Demand The projected total apparent power for the current demand period kVA 0.
PowerMonitor 5000 Unit Data Tables Appendix A LoggingResults.DataLog_FileName Table 139 - Table Properties CIP Instance Number 849 PCCC File Number ST58 No. of Elements 1 Length in Words 32 Data Type String Data Access Read Only Table 140 - LoggingResults.DataLog_FileName Data Table Element Number Type Tag Name Description Default Range 0 String Data_Log_File_Name 64 character file name: Datalog_YYYYMMDD_HHMMSS_hh ‘/0’ indicates no more file names to return.
Appendix A PowerMonitor 5000 Unit Data Tables LoggingResults.Data_Log Table 143 - Table Properties CIP Instance Number 851 PCCC File Number F60 No. of Elements 38 Length in Words 76 Data Type Real Data Access Read Only Table 144 - LoggingResults.
PowerMonitor 5000 Unit Data Tables Appendix A Table 144 - LoggingResults.Data_Log Data Table Element Number Type Tag Name Description Unit Range 24 Real DataLog_Parameter_19 25 Real DataLog_Parameter_20 If Record_Indicator =1, parameter value If Record_Indicator =2 = parameter index: reference to Data Log Parameter List table(1) 26 Real DataLog_Parameter_21 ±0…9.999E15 27 Real DataLog_Parameter_22 ±0…9.999E15 28 Real DataLog_Parameter_23 ±0…9.
Appendix A PowerMonitor 5000 Unit Data Tables LoggingResults.Energy_Log Table 145 - Table Properties CIP Instance Number 852 PCCC File Number F61 No. of Elements 35 Length in Words 70 Data Type Real Data Access Read Only Table 146 - LoggingResults.Energy_Log Data Table Element Number Type Tag Name Description 0 Real Record_Indicator Indicate meanings of the data in the record 1 Real Energy_ Record_Identifier. Internal unique record number # ±0…9.
PowerMonitor 5000 Unit Data Tables Appendix A Table 146 - LoggingResults.Energy_Log Data Table Element Number Type Tag Name Description Unit Range 26 Real GVAh Net Net gigaVA hours GVAh 0…9,999,999 27 Real kVAh Net kiloVA hours kVAh 0.000…999,999 28 Real kW Demand The average real power during the last demand period kW ± 0.000…9,999,999 29 Real kVAR Demand The average reactive power during the last demand period kVAR ± 0.
Appendix A PowerMonitor 5000 Unit Data Tables LoggingResults.LoadFactor.Log Table 147 - Table Properties CIP Instance Number 853 PCCC File Number F62 No. of Elements 40 Length in Words 80 Data Type Real Data Access Read Only Table 148 - LoggingResults.LoadFactor.Log Data Table Element Number Type Tag Name Description 0 Real LoadFactor_Record_Number The record number of this data. 1 Real LoadFactor_End_Date The date that this record was stored.
PowerMonitor 5000 Unit Data Tables Appendix A LoggingResults.TOU.Log Table 149 - Table Properties CIP Instance Number 854 PCCC File Number F63 No. of Elements 38 Length in Words 76 Data Type Real Data Access Read Only Table 150 - LoggingResults.TOU.Log Data Table Element Number Type Tag Name Description 0 Real TOU_Record_Number The record number of the log.
Appendix A PowerMonitor 5000 Unit Data Tables Table 150 - LoggingResults.TOU.Log Data Table Element Number Type Tag Name Description Units Range 28 Real On_Peak_kVAh_Net Net On Peak kiloVA hours kVAh 0…999,999 29 Real On_Peak_kVA_Demand On Peak Demand for kiloVA kVA 0.000…9,999,999 30…37 Real Resvd Reserved 0 LoggingResults.MIN_MAX.Log Table 151 - Table Properties CIP Instance Number 855 PCCC File Number F64 No.
PowerMonitor 5000 Unit Data Tables Appendix A LoggingResults.Alarm_Log Table 153 - Table Properties CIP Instance Number 856 PCCC File Number N65 No. of Elements 7 Length in Words 7 Data Type Int16 Data Access Read Only Table 154 - LoggingResults.Alarm_Log Data Table Element Number Type Tag Name Description 0 Int16 Alarm_Record_Identifier Used to verify record sequence when returning multiple records. 1 Int16 Alarm_Timestamp_Year The year when the record was recorded.
Appendix A PowerMonitor 5000 Unit Data Tables LoggingResults.Event_Log Table 155 - Table Properties CIP Instance Number 857 PCCC File Number N66 No. of Elements 9 Length in Words 9 Data Type Int16 Data Access Read Only Table 156 - LoggingResults.Event_Log Data Table Element Number Type Tag Name Description 0 Int16 Event_Record_Identifier Used to verify record sequence when returning multiple records. 1 Int16 Event_Timestamp_Year The year when the record was recorded.
PowerMonitor 5000 Unit Data Tables Appendix A LoggingResults.Setpoint_Log Table 157 - Table Properties CIP Instance Number 858 PCCC File Number F67 No. of Elements 18 Length in Words 36 Data Type Real Data Access Read Only Table 158 - LoggingResults.Setpoint_Log Data Table Element Number Type Tag Name Description 0 Real Setpoint_Record_Identifier Used to verify record sequence when returning multiple records. 1 Real Setpoint_Timestamp_Year The year when the record was recorded.
Appendix A PowerMonitor 5000 Unit Data Tables LoggingResults.Error_Log Table 159 - Table Properties CIP Instance Number 859 PCCC File Number N68 No. of Elements 24 Length in Words 24 Data Type Int16 Data Access Read Only Table 160 - LoggingResults.Error_Log Data Table Element Number Type Tag Name Description 0 Int16 Error_Record_Number The record number of the log.
PowerMonitor 5000 Unit Data Tables Appendix A Table 160 - LoggingResults.Error_Log Data Table Element Number Type Tag Name Description 18 Int16 Error_Active_Process_ID/Reserved7 The process No.
Appendix A PowerMonitor 5000 Unit Data Tables LoggingResults. TriggerLog_Setpoint_Info_File_Name (M6 model) Table 161 - Table Properties CIP Instance Number 866 PCCC File Number ST75 No. of Elements 1 Length in Words 32 Data Type String Data Access Read Only Table 162 - LoggingResults.
PowerMonitor 5000 Unit Data Tables Appendix A LoggingResults.TriggerData_Header (M6 model) Table 165 - Table Properties CIP Instance Number 862 PCCC File Number F71 No. of Elements 15 Length in Words 30 Data Type Real Data Access Read Only Table 166 - LoggingResults.
Appendix A PowerMonitor 5000 Unit Data Tables LoggingResults.TriggerData_Log (M6 model) Table 167 - Table Properties CIP Instance Number 861 PCCC File Number F70 No. of Elements 14 Length in Words 28 Data Type Real Data Access Read Only Table 168 - LoggingResults.
PowerMonitor 5000 Unit Data Tables Appendix A LoggingResults.Power_Quality_Log (M6 model) Table 169 - Table Properties CIP Instance Number 864 PCCC File Number F73 No. of Elements 32 Length in Words 64 Data Type Real Data Access Read Only Table 170 - LoggingResults.
Appendix A PowerMonitor 5000 Unit Data Tables Table 170 - LoggingResults. Power_Quality_Log Data Table Element Type Number Tag Name Description Unit Range 18 Real Event_Duration_mS Event duration in millisecond for sag/swell event, Event duration in cycles for WSB events mS 0…60000 19 Real Min_or_Max_Volts Min value of sag event or Max value of swell event. Volts +/0…9.999e15 20 Real Trip_Point The trip point that triggered the event # +/0…9.
PowerMonitor 5000 Unit Data Tables Appendix A LoggingResults.Waveform_Log (M6 model) Table 175 - Table Properties CIP Instance Number 871 PCCC File Number F80 No. of Elements 43 Length in Words 86 Data Type Real Data Access Read Only Table 176 - LoggingResults.
Appendix A PowerMonitor 5000 Unit Data Tables Table 176 - LoggingResults. Waveform_Log Data Table Element Number Type Tag Name Description Unit Range 11 Real X_(0 + Order * 32) The returned value X_(h) for the spectral component specified by Channel at harmonic h X_(h) = RMS magnitude if Mag_Angle = 0 X_(h) = Angle if Mag_Angle = 1 V, A, or degrees, depending on value of Channel and Mag_Angle +/- 0…9.999E15 12 Real X_(1 + Order * 32) +/- 0…9.999E15 13 Real X_(2 + Order * 32) +/- 0…9.
PowerMonitor 5000 Unit Data Tables Appendix A PowerQuality.RealTime_PowerQuality Table 177 - Table Properties CIP Instance Number 845 PCCC File Number F54 No. of Elements 56 Length in Words 112 Data Type Real Data Access Read Only Table 178 - PowerQuality.
Appendix A PowerMonitor 5000 Unit Data Tables Table 178 - PowerQuality.RealTime_PowerQuality Data Table Element Type Number Tag Name Description Units Range 29 Real V3_IEC_THD_% V3-N IEC Total Harmonic Distortion % 0.00…100.00 30 Real VN_G_IEC_THD_% VGN-N IEC Total Harmonic Distortion % 0.00…100.00 31 Real Avg_IEC_THD_V_% Average V1/V2/V3 to N IEC Total Harmonic Distortion % 0.00…100.00 32 Real V1_V2_IEC_THD_% V1-V2 IEC Total Harmonic Distortion % 0.00…100.
PowerMonitor 5000 Unit Data Tables Appendix A PowerQuality.Harmonics_Results (M6 model) Table 179 - Table Properties CIP Instance Number 860 PCCC File Number F69 No. of Elements 37 Length in Words 74 Data Type Real Data Access Read Only Table 180 - PowerQuality.
Appendix A PowerMonitor 5000 Unit Data Tables Table 180 - PowerQuality.Harmonics_Results Data Table Element Type Number Tag Name Description Units Range 5 Real X_(0 + Order * 32) Real X_(1 + Order * 32) 7 Real X_(2 + Order * 32) V, A, or degrees, depending on value of Channel 0…9.999E15 6 The returned value X_(h) (RMS magnitude or angle) for the spectral component specified by Channel at harmonic h 8 Real X_(3 + Order * 32) 0…9.999E15 9 Real X_(4 + Order * 32) 0…9.
PowerMonitor 5000 Unit Data Tables Appendix A PowerQuality.IEEE1159_Results (M6 model) Table 181 - Table Properties CIP Instance Number 863 PCCC File Number F72 No. of Elements 26 Length in Words 52 Data Type Real Data Access Read Only Table 182 - PowerQuality.
Appendix A PowerMonitor 5000 Unit Data Tables PowerQuality.Synchro_Phasor_Results Table 183 - Table Properties CIP Instance Number 894 PCCC File Number F103 No. of Elements 26 Length in Words 52 Data Type Real Data Access Read Only Table 184 - PowerQuality.
PowerMonitor 5000 Unit Data Tables Appendix A PowerQuality.IEEE519_ Results (M6 model) The PowerMonitor 5000 M6 model returns short- and long-term rolling average harmonic distortion data for the fundamental and the first 40 harmonic frequencies. These results are presented in six similar data tables. Table 185 - Table Properties Data Table Name CIP Instance Number PCCC File No. PowerQuality.IEEE519_CH1_ShortTerm_Results 895 F104 PowerQuality.IEEE519_CH2_ShortTerm_Results 896 F105 PowerQuality.
Appendix A PowerMonitor 5000 Unit Data Tables Table 186 - PowerQuality.IEEE519 Results Data Table Template Element Type Number Tag Name Description Units Range 0 Real Metering_Date_Stamp Date of cycle collection MMDDYY MMDDYY 0…123199 1 Real Metering_Time_Stamp Time of cycle collection hhmmss hhmmss 0…235959 2 Real Metering_Microsecond_Stamp Microsecond of cycle collection uS 0.000…999999 3 Real _Fundamental_IEEEE519_ The fundamental RMS magnitude.
PowerMonitor 5000 Unit Data Tables Appendix A Table 186 - PowerQuality.IEEE519 Results Data Table Template Element Type Number Tag Name Description Units Range 38 Real _36th_Harmonic_IEEE519_ Percent of Fundamental % 0.000…100.
Appendix A PowerMonitor 5000 Unit Data Tables Table 188 - Substitution Table For: Substitute: To return these harmonic results: Total Total (3-phase) power L1 Line (Phase) 1 power L2 Line (Phase) 2 power L3 Line (Phase) 3 power V1_N Line 1 to Neutral voltage V2_N Line 2 to Neutral voltage V3_N Line 3 to Neutral voltage VN_G Neutral to Ground voltage V1_V2 Line 1 to Line 2 voltage V2_V3 Line 2 to Line 3 voltage V3_V1 Line 3 to Line 1 voltage I1 Line 1 current I2 Line 2 cur
PowerMonitor 5000 Unit Data Tables Appendix A Table 189 - PowerQuality.Harmonic Results Data Table template, H1 order range (DC …31) Element Number Type Tag Name Description Units Range 0 Real Metering_Date_Stamp Date of cycle collection MMDDYY MMDDYY 0…123199 1 Real Metering_Time_Stamp Time of cycle collection hhmmss hhmmss 0…235959 2 Real Metering_Microsecond_Stamp Microsecond of cycle collection uS 0.
Appendix A PowerMonitor 5000 Unit Data Tables Table 189 - PowerQuality.Harmonic Results Data Table template, H1 order range (DC …31) Element Number Type Tag Name Description Units Range 24 Real __h21_ _ The value of the specified harmonic component: RMS magnitude or Angle 0…9.999E15 25 Real __h22_ _ Same as string in Tag Name: kW kVAR kVA Volts Amps 26 Real __h23_ _ 0…9.
PowerMonitor 5000 Unit Data Tables Appendix A Table 190 - PowerQuality.Harmonic Results Data Table template, H2 order range (32…63) Element Number Type Tag Name Description Units Range 0 Real Metering_Date_Stamp Date of cycle collection MMDDYY MM:DD:YY 0…123199 1 Real Metering_Time_Stamp Time of cycle collection hhmmss hhmmss 0…235959 2 Real Metering_Microsecond_Stamp Microsecond of cycle collection uS 0.
Appendix A PowerMonitor 5000 Unit Data Tables Table 190 - PowerQuality.Harmonic Results Data Table template, H2 order range (32…63) Element Number Type Tag Name Description Units Range 25 Real __h54__ The value of the specified harmonic component: RMS magnitude or Angle 0…9.999E15 26 Real __h55__ Same as string in Tag Name: kW kVAR kVA Volts Amps 27 Real __h56__ 0…9.
Appendix B Technical Specifications Table 191 - Accuracy and Range Parameter Accuracy in % of Reading at 25 °C (77 °F) 50/60 Hz Unity Power Factor Rating, nom/Metering Range, max Applies to 1426-M5 Voltage Sense Inputs: V1, V2, V3, VN ±0.1% VG X Line-neutral RMS: 398V AC/15…660V AC Line-line RMS: 690V AC /26…1144V AC X Connect to power system earth ground only. This is a functional ground. Current Sense Input: I1, I2, I3, I4 ±0.1% X 5 A / 0.05 - 15.6 A RMS Frequency ±0.
Appendix B Technical Specifications Table 193 - Input and Output Ratings Parameter Rating Voltage Sense Inputs: V1, V2, V3, VN Input Impedance: 5M ohm min Input current: 1 mA max Current Sense Inputs: I1, I2, I3, I4 Overload Withstand: 22 A Continuous, 200 A for one second Burden: Negligible Impedance: Negligible Maximum Crest Factor at 5 A is 4.0 Starting Current: 5 mA Status Inputs Contact Closure (Internal 24V DC) KYZ Output Solid State KYZ: 80 mA at 240V AC/V DC Control Relay ANSI C37.
Technical Specifications Appendix B Table 195 - General Specifications Certifications Parameter Maximum Rating Voltage Terminal Blocks 18…14 AWG (0.75…2.5 mm2), 75 °C Minimum Copper Wire only Recommended torque 1.5 N•m (13.3 lb•in) Current Sensing Input 12 AWG (4 mm2), 75 °C Minimum Copper Wire only Recommended torque: N/A Control Power Terminal Block 22…14 AWG (0.25…2.5 mm2), 75 °C Minimum Copper Wire only Recommended torque 0.63 N•m (5.6 lb•in) Input/Output (I/O) Terminal Block 20…14 AWG (0.
Appendix B Technical Specifications EMC Directive This product is tested to meet Council Directive 2004/108/EC Electromagnetic Compatibility (EMC) and the following standards, in whole, documented in a technical construction file. EN 61326-1:2006 WARNING: This is a class A product that is intended for use in an industrial environment. In a residential, commercial, or light industrial environment, it can cause radio interference. This product is not intended to be installed in a residential environment.
Appendix C PowerMonitor 5000 Display Module Application Summary Introduction The PowerMonitor 5000 Display Module, catalog number 1426-DM, is a PanelView Component C400 terminal with factory-installed applications. This display module displays key information from one, two, or three PowerMonitor 5000 units. Minimal setup for communication is required.
Appendix C PowerMonitor 5000 Display Module Application Summary 4. Select PM5000DM-# and click Edit. The # is either 1, 2, or 3 depending on the number of power monitors being monitored. 5. Once the PanelView Explorer window opens, click the Communication tab. On the Communication tab is a Controller Settings heading listing the power monitors in the application.
PowerMonitor 5000 Display Module Application Summary Appendix C 6. Update the IP addresses and click the Validate Application icon to validate the application. 7. Once the application has been validated, click the blue floppy disk icon to save the program. 8. Close the dialog box to return to the PanelView Explorer Startup window.
Appendix C PowerMonitor 5000 Display Module Application Summary 9. In the start-up window, select PM5000DM-l and click Run. 10. Once the Application Mode changes to 'Running', click Sign Off in the upper right to close the dialog box.
PowerMonitor 5000 Display Module Application Summary Appendix C Navigation This section describes the navigation for the PowerMonitor 5000 Display Module application. All screen captures in this section are for the application that uses three power monitors. The Main screen is displayed on startup. From this screen, you can select any of the five other screens. • Press Overview to display the Overview screen. This screen is unique as it displays values for up to three power monitors simultaneously.
Appendix C PowerMonitor 5000 Display Module Application Summary • Press V,I,F to open the following screen. By default, pressing any button displays data from the power monitor whose IP address was entered first. The buttons along the bottom select another power monitor. Any button highlighted in blue indicates the selected screen and power monitor. The VIF screen for PM#2 is shown below.
PowerMonitor 5000 Display Module Application Summary Appendix C • This is the Power screen. • This is the Power Quality screen.
Appendix C PowerMonitor 5000 Display Module Application Summary • This is the Energy Demand screen.
Appendix D PowerMonitor 5000 Waveform Capture and Compression (M6 model) Waveform recordings in the PowerMonitor 5000 M6 model consist of a series of cycle-by-cycle magnitude and angle data for each spectral component (harmonic) from DC through the 127th harmonic. To reduce the size of waveform records without losing significant resolution, the data is compressed before writing to the waveform file.
Appendix D PowerMonitor 5000 Waveform Capture and Compression (M6 model) Table 198 - 12-bit Encoding Byte offset 0 Byte offset 1 Low 8 bits of X(h) Byte offset 3 High 4 bits of X(h) Low 4 bits of X(h+1) High eight bits of X(h+1) Where X(h) is the value (magnitude or angle) of the harmonic at order h. Magnitude Data Bytes 0…63 contain 32-bit encoded magnitudes V(h) and I(h) for h = DC thru 15. Byte 64 contains the exponent offset for use in the 12-bit encoded data that follows.
PowerMonitor 5000 Waveform Capture and Compression (M6 model) Appendix D Angle Data Byte 0 contains the exponent offset for use in the 16- and 12-bit encoded data that follows. Bytes 1…32 contain 16-bit encoded magnitudes V(h) and I(h) for h = DC…15. The remaining bytes hold the remaining harmonic magnitude values in12-bit encoding.
Appendix D PowerMonitor 5000 Waveform Capture and Compression (M6 model) Waveform File Format The tables below illustrate the waveform file format.
Glossary The following terms and abbreviations are used throughout this manual. For definitions of terms not listed here, refer to the Allen-Bradley Industrial Automation Glossary, publication AG-7.1. Amperes The units of electrical current or rate of flow of electrons. One volt across one ohm of resistance causes a current flow of one ampere. A flow of one coulomb per second equals one amp. Apparent Power The product of voltage magnitude and current magnitude in a circuit.
Glossary Demand Hours The equivalent number of hours in a month during which the peak demand is fully utilized. In other words, if energy consumption for the current month is X kwhr and the peak demand is Y kW, then the demand hours is equal to X/Y hours. The higher the number of demand hours, the better the demand leveling situation, and the more effectively demand is being used.
Glossary Neutral The conductor chosen as the return path for the current from the load to the source. It is also a voltage reference point in a power system. Ohm The unit of electrical resistance. One ohm is the value of resistance through which a potential difference of one volt maintains a current flow of one ampere. Peak Demand The highest average load over a utility specified time interval during a billing period.
Glossary Real Power The component of apparent power that represents real work in an alternating current circuit. It is expressed in watts and is equal to the apparent power times the power factor. Resistance The property of a substance that impedes current flow and results in the dissipation of power in the form of heat. The unit of resistance is the ohm. One ohm is the resistance through which a difference of potential of one volt produces a current of one ampere.
Glossary Watt Hour (Whr) The number of watts used in one hour. Because the power usage varies, it is necessary to integrate this parameter over time. Power flow can be either forward or reverse. Wattmeter An instrument for measuring the real power in an electric circuit. Its scale is usually graduated in watts, kilowatts, or megawatts. Volt Ampere Reactive Hours The number of VARs used in one hour. Because the value of this parameter (VARH) varies, it is necessary to integrate it over time.
Glossary Notes: 388 Rockwell Automation Publication 1426-UM001F-EN-P - November 2013
Index A accessory kit 20 overcurrent protection 31 account classes and privileges 172 admin 172 application 172 USB admin 172 user 172 accuracy and range 367 adding optional communcation 223 additional resources 9 addressing CIP 185 CSP 185 symbolic 185 alarm log 79 codes and descriptions 137 logged parameters 136 results 136 angle data 381 auto return data order 104 automatic virtual wiring correction 54 averaging of metering results 53 B basic metering 51 set-up parameters 52 billing 12 C calendar 173
Index data types DWORD 185 INT16 185 REAL 185 string 185 daylight saving time 173, 174 demand calculation formula 63 demand metering 62 date and time 173 delay 65 end-of-interval signal 64 number of periods 65 period length 65 setup 64 demand power factor formula 63 demand response 12 detection of power quality events 52 device indicator 13 DeviceNet communication 38, 182 communication command 186 communication rate 183 communication setup 47 connection 39 I/O connection 203 mac id 183 object model 188 dim
Index G general codes 131 general specifications 369 generic Ethernet connection version 19 and earlier 202 glossary terms 383 ground the unit 20 ground wiring terminal 13 grounding mounting surface 20 wire connection 20 H harmonic analysis 75 IEC DIN 75 IEEE THD 75 total harmonic distortion 75 harmonic distortion crest factor 75 harmonic analysis results 76, 78 harmonic magnitude and angle 76 harmonic power 76 k-factor 75 harmonic magnitude 76 harmonic power 76 I I/O connection ControlNet 208 DeviceNet
Index network indicator 13 nominal system frequency 52 nominal system voltage 52 O object model object class list 187, 188 Off_Peak_Days 101 OPC server 197 test 199 other functions 15 overcurrent protection 31 overview 11 P panel mounting 18 PanelView C400, terminal set-up 371 parameter configuration 188 peak hours 101 phase angle 54, 57 Point of Common Coupling (PCC) 90 power factor phase angle 54 power factor ranges 53 power frequency variations 89 power indicator 13 power metering 67 power quality 12
Index status inputs 13, 155 features status inputs 29 Setup 155 string 185 Studio 5000 Engineering and Design Environment 189 sub-billing 12 subnet mask default 35 symbolic tag addressing 184, 185 symmetrical component analysis 70 system clock synchronize 175 T terminal 371 terminal block layout 19 THD 75 current 88 voltage 88 time of use log logged parameters 128 results 128 time zones 176 Time_Of_Use_AutoStore 101 Total Demand Distortion (TDD) 90 total harmonic distortion 75 U UDT files 207 UL/CUL 369
Index 394 Rockwell Automation Publication 1426-UM001F-EN-P - November 2013
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.
