DC Variable Electronic load for SMPS Testing

International Research Journal of Engineering and Technology (IRJET) e-ISSN: 2395-0056
Volume: 05 Issue: 01 | Jan-2018 www.irjet.net p-ISSN: 2395-0072
© 2018, IRJET | Impact Factor value: 6.171 | ISO 9001:2008 Certified Journal | Page 1070
DC Variable Electronic load for SMPS Testing
G A Rathy1, Aravind balaji2
1Associate Professor, Electrical Department, NITTTR, Chennai, India
2R&D Engineer, Bharathi Enterprises, Chennai, India
---------------------------------------------------------------------***---------------------------------------------------------------------
Abstract -As technology is constantly advancing, demands
for quality test instruments increase due to the need for
making better and accurate measurements to accommodate
newer technologies. DC Electronic loads are one such
instrument that will aid in testing various settings,
configurations, schemes, and methodologies The intention of
this application note is to provide a general scope of a DC
load's usage. As regulated-power supply technology evolves,
testing methods for design verification and product function
require more sophisticated electronicequipment.Thedifferent
power supply architectures and output combinations also
dictate the need for versatile test instruments that can
accommodate a broad range of specifications. As a result, one
testing requirement that has been growing in importance is
the method of loading the power supply under test. The need
for a higher degree of load control is due to test sophistication.
Thus this paper presents a Variable electronic load using
MOSFET switching to load the SMPS.
Key Words: SMPS, Electronic load, MOSFET, test
instruments.
1. INTRODUCTION
The Electronic loads have found a variety of
applications ranging power converter testing to current
modulation. A large range of power sources can be tested
using an electronic load from converters, invertersandUPSs
to electrochemical sources such as batteries and fuel cells.
They are easy-to-use and provide much higher throughput
than resistors when varying loads are needed. For battery
test, they provide a constant loading which can greatly
reduce the time for test when compared to resistor load
banks. Electronic loads can also simulate various power
states of a device such as a handheld which may have sleep,
power conservation and full powermodes.They alsopresent
a complex electronic load which more closely simulates the
real environment of the power source. Modulation uses
improve the performance of programmable power supplies
by providing faster transient response.
1.1 .SMPS
The multiple DC voltage levels required by many electronic
devices, designers need a way to convert standard power-
source potentials into the voltages dictated by the load.
Voltage conversion must be a versatile, efficient, reliable
process. Switch-modepower supplies(SMPSs)arefrequently
used to provide the variouslevelsofDCoutputpowerneeded
for modern applications, and are indispensable in achieving
highly efficient, reliable DC-DC power-conversion systems.
SMPSs can convert a DC input voltage into a different DC
output voltage, depending on the circuit topology. While
there are numerousSMPS topologiesusedin theengineering
world, three are fundamental and seen most often. These
topologies are classified according to their conversion
function: step-down (buck), step-up (boost), and step-
up/down (buck-boost or inverter). All three fundamental
topologies include a MOSFET switch, a diode, an output
capacitor, and aninductor. The MOSFET, whichistheactively
controlled component in the circuit, is interfaced to a
controller. This controller applies a pulse-width-modulated
(PWM) square-wave signal to the MOSFET's gate, thereby
switching the device on and off. To maintain a constant
output voltage, the controller sensestheSMPSoutputvoltage
and varies the duty cycle (D) of the square-wave signal,
dictating how long the MOSFET is on during each switching
period (TS).
1.2. ELECTRONIC LOAD
Electronic loads provide a very fast method to test
converters of all types DC-DC, AC-DC and DC-AC. Load
regulation, over current protection, noise testing (with
appropriate filtering), and overpower protection can all be
very quickly tested in a laboratory or production
environment. The flexibility in operating range of the
electronic load also allows a quick verification of power
supply ratings. Electronic loads can be used to directly test
the capacity of a battery. This can be done in constant power
mode (CP) to provide a consistent drain thatdoesnotchange
asthe battery voltage drops. Electronic loadsarealsousedin
battery forming operations as part of the charge/discharge
cycling. With the constant drive to find high power density
batteries for both handheld applicationsandhybridvehicles,
battery controller development and test are a common
application for electronic loads. As discharge profiles are
specific to a particular battery design and/ or charge state,
the ability of a load to produce quick changes in load are
essential for this application.
In a sense electronic loads are the antithesis of
power supplies, i.e. they sink or absorb power while power
supplies source power. In another sense they are very
similar in the way they regulate constant voltage (CV) or
constant current (CC). When used to load a DUT, which
inevitably is some form of power source, conventional
practice is to use CC loading for devices that are by nature
voltage sources and conversely use CV loading for devices
that are by nature current sources. However most all

electronic loads also feature constant resistance (CR)
operation as well. Many real-world loads are resistive by
nature and hence it is often useful to test power sources
meant to drive such devices with an electronic load
operating in CR mode. The CC and CV modesare verysimilar
in operation for both a power supply and an electronic load.
An electronic load CC mode operation is depicted in Figure
below.
Fig -1: CC Mode operation
The load, operating in CC mode, is loading the
output of an external voltage source as shown in Figure1.
The current amplifier is regulating theelectronicload’sinput
current by comparing the voltage on the current shunt
against a reference voltage, which in turn is regulating how
hard to turnon the load FET. The correspondingI-Vdiagram
for this CC mode operation is shown in Figure 2 . The
operating point is where the output voltage characteristicof
the DUT voltage source characteristic intersects the input
constant current load line of the electronic load.
Fig -2: Electronic load V-I diagram
CV mode is very similar to CC mode operation, asdepictedin
Figure 3. However, instead of monitoring the input current
with a shunt voltage, a voltage control amplifier compares
the load’s input voltage, usually through a voltage divider,
against a reference voltage. When the input voltage signal
reaches the reference voltage value the voltage amplifier
turns the load FET on as much as needed to clamp the
voltage to the set level.
Fig -3: CV Mode operation
A battery being charged is a real-world example of a CVload,
charged typically by a constant current source. The
corresponding I-V diagram for CV mode operation is
depicted in Figure 4.
Fig -4: Electronic load I-V diagram
1.3. ANALOG COMPARATOR
The Op-amp comparator as shown in Figure 5 compares
one analogue voltage level with another analogue voltage
level, or some preset reference voltage, VREF and produces
an output signal based on this voltage comparison. In other
words, the op-amp voltage comparator compares the
magnitudes of two voltage inputs and determines which is
the largest of the two. Voltage comparators on the other
hand, either use positive feedback or no feedback at all
(open-loop mode) to switchitsoutputbetweentwosaturated
states, because in the open-loop mode the amplifiers voltage
gain is basically equal to AVO. Thenduetothishighopenloop
gain, theoutput from the comparator swingseitherfullytoits
positive supply rail, +Vcc or fully to its negative supply rail, -
Vcc on the application of varying input signal which passes
some preset threshold value.
Theopen-loop op-amp comparator isananaloguecircuitthat
operates in its non-linear region as changes in the two
analogue inputs, V+ and V- causes it to behave like a digital
bistable device as triggering causes it to have two possible
output states, +Vcc or -Vcc. Then we can say that the voltage
comparator is essentially a 1-bit analogue to digital
converter, as the input signal is analogue but the output
behaves digitally.

Fig -5: Analog comparator
With reference to the op-amp comparator circuit above, lets
first assume that VIN is less than the DC voltage level at
VREF, ( VIN < VREF ). Asthe non-inverting (positive)inputof
the comparator is less than the inverting (negative) input,
the output will be LOW and at the negative supply voltage, -
Vcc resulting in a negative saturation of the output. increase
the input voltage, VIN so that its value is greater than the
reference voltage VREF on the inverting input, the output
voltage rapidly switches HIGH towards the positive supply
voltage, +Vcc resulting in a positivesaturation of the output.
If we reduce again the input voltage VIN, so that it is slightly
lessthan the reference voltage, theop-amp’soutputswitches
back to its negative saturation voltage acting as a threshold
detector.depending upon the circuit asshown in the figure6
the reference voltage can be calculated. It can be determined
between 0 to VCC.
Fig -6: Comparator Reference voltage
2. CIRCUIT IMPLEMENTATION
The basic SMPS loading circuit is illustrated below in which
the electronic load is in parallel with the SMPS and the load
current Iload flows across the load and SMPS
Fig -7: Basic Load circuit
The Figure7 given below shows the circuit diagram of the
power circuit of the DC electronic load in which regulated
+12v is been generated using a rectifier and a regulator
which are been provided as an power source for the
comparator here operational amplifier is been used as
analog comparator.thermister are been providedtomonitor
the temperature and if it’s not of desiredtemperaturefanout
are been provided to turn on the fan using a transistorwhich
acts as an switch. Asfar as control circuit is concernitisused
to switch the MOSFET depending upon the load current id
required the figure given below shows the control circuit in
which MOSFET is been switch on dependingupontheanalog
comparator output.
Fig 8: Power circuit
Fig -9: Control circuit

The power circuit and control circuit shown in Figure 8 &9
can provide up to 6A of load current, this is achieved by
using six MOSFET switch Q1 to Q6 in which each MOSFET
provide 1A of load totally providing 6A using thoseMOSFET.
LM358 which act as an analog comparator is used to
compare the reference voltage with the input voltage which
varies from 0 to 1V. Hence varies the switching time of the
MOSFET which varied the load current acrosseachMOSFET.
The reference voltage is been varied depending upon the
10K load control potentiometer is used for varying the load
current as required.
The load input voltage is limited mainly by the drain to
source voltage (Vds) rating of the MOSFET, and current by
the value of current sense resistor. Take note, while
connecting the source to the load, you should calculate the
power dissipation carefully to retain the MOSFET always in
the safe operating area (SOA) otherwise it will be deep-fried
as soon as its die temperature exceeds the safety margin.
Regarding heatsink selection for theMOSFET,astandardTO-
247AC type with a thermal resistance of 0.24C/W should be
a good pick. Since the typical junction-to-case thermal
resistance of MOSFET IRF250 is 1.00C/W, case-to-sink
thermal resistance is 0.24C/W, and maximum operating
temperature range of 1750 C, the maximum power
dissipation allowed will be 1750C – 25 0C (ambient
temperature) / 40 C/W (total thermal resistance) around
37W. Similarly, try to use a 1R/10W-50W aluminum clad
power resistor as the current sense resistor. If possible opt
for the better TO-220 type power resistor (naturally with a
heatsink) as it’s more convenient and efficient.Also,it’sgood
to attach a digital ammeter in to the load path, to measure
the current drawn from the source.
3. HARDWARE IMPLEMENTATION
Fig -10: Hardware Implementation
The figure10 given below shows the hardware
implementations of the electronic load in which IRF250
MOSFET are beenused with properheat sink andcoolingfan
to dissipate the heat induced due to loading effect. Current
meter are been provided to indicate the current and ten turn
potentiometer are been used to get a precise value of
variation between desiredloadcurrent.Metalcasingarebeen
provided to reduce shock and physical damage.
3.RESULT
Fig -11: Result
The figure 11 showsthe verification of the DC load outputin
which a 24V SMPS is been loaded with the electronic load .
AC input is been applied to one end of the SMPS and the load
is been connected to the output of the SMPS. By varying the
potentiometer the output load current current can bevaried
from 0 to 6A here in the figure the SMPS is been loaded with
3.6A load.
4. CONCLUSIONS
Thus this paper presents the implementation of the DC
variable electronic load in which by using theMOSFETasthe
load to provide the desired current the output load current
can be varied upto 6A. The number of MOSFET can be
increased to increase the output load current for which
desired reverse current protection circuits and high current
rated MOSFET are to be used. Proper heat sinking method is
to be followed to dissipate excess heat.
REFERENCES
[1] Kazerani, M., “A High-Performance Controllable DC
Load”, IEEE International Symposium on Industrial
Electronics, ISIE 2007, pp. 1015-1020, June, 2007.
[2] Durán, E., Andújar, J.M., Segura, F., Barragán, A.J., “A
High-Flexibility DC Load for Fuel Cell and Solar Arrays
power sources based on DC–DC converters”, Applied
Energy, Vol. 88, Issue 5, pp. 1690-1702, May 2011.
[3] Canesin, C.A., Seixas, F.J.M., Seixas, C.M., “A 300A
Dynamic Electronic Load BasedOnModifiedBuck-Boost
Interleaved Converter”, Eletrônica de Potência, Vol. 11,
No. 3, pp. 161-166, 2006.
[4] Kuai, Y., Yuvarajan, S., “An Electronic Load for Testing
Photovoltaic Panels”, Journal of PowerSources,Vol.154,
pp. 308-313, 2006.

[5] Huilin, O., Gang, W., “The Study of Electronic Load Based
on DSP”, First International Conference on Power
Electronics Systems and Applications, pp. 285-290,
November 2004.
[6] Zhu Jingang, “Design of Intelligent Electronic
Load,”Experimental Technology and Management, Vol.
06, pp. 27-29, 58, 2006.
[7] [2]Gao Jiaying, Gao Yufeng, and Liu Yalong, “Researchof
constant-current Discharge Equipment with New Type
Electronic Load,”
[8] w.amrel.com /AMRELPowerProducts/index.html. .
[9] [7] B&K Precision Corporation, "150 DC Electronic
Load," November 2008. [Online].Available:
[10] http://www.bkprecision.com/products/model/8540/
150-w-dcelectronic-load.html.

DC Variable Electronic load for SMPS Testing

More Related Content

What's hot (20)

Similar to DC Variable Electronic load for SMPS Testing (20)

More from IRJET Journal (20)

Recently uploaded (20)

DC Variable Electronic load for SMPS Testing