User manual

ManualsBrandsEA ELEKTRO-AUTOMATIK ManualsPower Supplies & Mains AdaptersElectrical load EA-EL 3200-25 B 200 Vdc 25

Page 27

EA Elektro-Automatik GmbH

Helmholtzstr. 31-37 • 41747 Viersen

Germany

Fon: +49 2162 / 3785-0

Fax: +49 2162 / 16230

www.elektroautomatik.de

ea1974@elektroautomatik.de

EL 3000 B Series

3.2.2 Current regulation / constant current / current limitation

Current regulation is also known as current limitation or constant current mode (CC) and is fundamental to the

normal operation of an electronic load. The DC input current is held at a predetermined level by varying the internal

resistanceaccordingtoOhm’slawR=U/Isuchthat,basedontheinputvoltage,aconstantcurrentows.Once

the current has reached the adjusted value, the device automatically switches to constant current mode. However,

if the power consumption reaches the adjusted power level, the device will automatically switch to power limitation

and adjust the input current according to I

MAX

= P

SET

/ U

, even if the maximum current set value is higher. The

current set value, as determined by the user, is always and only an upper limit.

While the DC input is switched on and constant current mode is active, the condition “CC mode active” will be

shown on the graphics display by the abbreviation CC, as well it will be passed as a signal to the analog interface

and stored as internal status which can be read via digital interface.

3.2.3 Resistance regulation / constant resistance

Inside electronic loads, whose operating principle is based on a variable internal resistance, constant resistance

mode(CR)isalmostanaturalcharacteristic.Theloadattemptstosettheinternalresistancetotheuserdened

value by determining the input current depending on the input voltage according to Ohm’s law I

= U

/ R

SET

The internal resistance is naturally limited between almost zero and maximum (resolution of current regulation

tooinaccurate).Astheinternalresistancecannothaveavalueofzero,thelowerlimitisdenedtoanachievable

minimum. This ensures that the electronic load, at very low input voltages, can consume a high input current from

the source, up to the maximum.

While the DC input is switched on and constant resistance mode is active, the condition “CR mode active” will

be shown on the graphics display by the abbreviation CR, as well it will be stored as internal status which can be

read via digital interface.

3.2.4 Power regulation / constant power / power limitation

Power regulation, also known as power limitation or constant power (CP), keeps

theDCinputpowerofthedeviceattheadjustedvalue,sothatthecurrentowing

from the source, together with the input voltage, achieves the desired value. Power

limitation then limits the input current according to I

= P

SET

/ U

as long as the

power source is able to provide this power.

Power limitation operates according to the auto-range principle such that at lower

inputvoltageshighercurrentcanowandviceversa,inordertomaintainconstant

power within the range P

(see diagram to the right).

While the DC input is switched on and constant power operation is active, the con-

dition “CP mode active” will be shown on the graphic display by the abbreviation

CP, as well it will be stored as internal status which can be read via digital interface.

Constant power operation impacts the internal set current value. This means that the maximum set current may

notbereachableifthesetpowervalueaccordingtoI=P/Usetsalowercurrent.Theuserdenedanddisplayed

set current value is always the upper limit only.

3.2.5 Dynamic characteristics and stability criteria

The electronic load is characterised by short rise and fall times of the current, which are achieved by a high band-

width of the internal regulation circuit.

In case of testing sources with own regulation circuits at the load, like for example power supplies, a regulation

instability may occur. This instability is caused if the complete system (feeding source and electronic load) has too

littlephaseandgainmarginatcertainfrequencies.180°phaseshiftat>0dBamplicationfullstheconditionfor

an oscillation and results in instability. The same can occur when using sources without own regulation circuit (eg.

batteries), if the connection cables are highly inductive or inductive-capacitive.

The instability is not caused by a malfunction of the load, but by the behaviour of the complete system. An improve-

ment of the phase and gain margin can solve this. In practice, a capacity is directly connected to the DC input of

theload.Thevaluetoachievetheexpectedresultisnotdenedandhastobefoundout.Werecommend:

80Vmodels:1000μF....4700μF

200Vmodels:100μF...470μF

360 V models: 68μF...220μF

500Vmodels:47μF...150μF

750Vmodels:22μF...100μF