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EXPERIMENTAL STUDY AND ANALYSIS OF POWER QUALITY ON HARMONIC MEASUREMENTRashmi Athiya 1
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Article Type: Research Article
Article Citation: Rashmi Athiya, and
Dr. A.K. Sharma. (2020). EXPERIMENTAL STUDY AND ANALYSIS OF POWER QUALITY ON
HARMONIC MEASUREMENT. International Journal of Research -GRANTHAALAYAH, 8(6), 259-262.
https://doi.org/10.29121/granthaalayah.v8.i6.2020.571
Received Date: 10 May 2020
Accepted Date: 30 June 2020
Keywords:
Experimental Approach
Power Quality Monitoring
Total Harmonic Distortions
ABSTRACT
In this paper, we are study the measurement of harmonic distortion with the help of experimental approach in which included the various equipment and loads such as Experimental setup, Indicator, A.C. power supply, circuit with transformer, switch for different loads, different loads (Filament bulb, CFL and LED).
1. INTRODUCTION
We are getting the different harmonic distortions using applied load. The electrical power quality is very necessary to improve for increasing the working life of different loads (Filament bulb, CFL and LED). The various types of faults are produced in power supply system using electronic device and other appliances. The electronic loads are mostly used in domestic and industrial appliances, this type load are created harmonic distortions in power supply system. The monitor and its control are very necessary for power system stability.
2. EXPERIMENTAL SETUP
Figure 1: Experimental setup
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Figure 2: Indicator |
Figure 3: A.C. power
supply |
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Figure 4: circuit with transformer |
Figure 5: switch for different loads |
Figure 6: different loads |
3. RESULTS AND DISCUSSION
Table
3.1: Reading
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Sr. No. |
Reading without Filter circuit in Hz |
Reading with Filter circuit in Hz |
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1 |
50.10 Hz |
49.87 Hz |
Table 3.2: Reading with Parameter
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Sr. No. |
Parameter |
Reading without Filter circuit |
Reading with Filter circuit |
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1 |
V1 |
234.43 V |
232.01 V |
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2 |
I1 |
59.94ma |
63.43ma |
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3 |
P1 |
11.29 W |
12.237 W |
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4 |
S1 |
14.187 VA |
14.894 VA |
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5 |
Q1 |
8.498Var |
8.628 Var |
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6 |
ø1 |
38.11 |
34.00 |
Table 3.3: Applied Load with Total harmonic distortions without using Filter circuit
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Sr. No. |
Applied Load |
Total harmonic distortions |
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1 |
Filament bulb (100 Watts) |
4.56% |
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2 |
CFL (15Watts) |
8.45% |
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3 |
LED (14Watts) |
8.89% |
Table 3.4: Applied Load with Total harmonic distortions using Filter circuit
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Sr. No. |
Applied Load |
Total harmonic distortions |
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1 |
Filament bulb (100 Watts) |
1.21% |
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2 |
CFL (15Watts) |
2.03% |
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3 |
LED (14Watts) |
2.58% |
4. CONCLUSION
We are finding out the total harmonic distortions without using Filter circuit such as 4.56% using Filament bulb (100 Watts), 8.45% using CFL (15Watts), 8.89% using LED (14Watts) and using Filter circuit such as 1.21%using Filament bulb (100 Watts), 2.03%using CFL (15Watts), 2.58%using LED (14Watts).
SOURCES OF FUNDING
None.
CONFLICT OF INTEREST
None.
ACKNOWLEDGMENT
None.
REFERENCES
[1]
Hunter,
I., “Power quality issues-a distribution company perspective”, Power
Engineering Journal, Vol. 15, No. 2, 2001.
[2]
S.,
Abdel-Rahman, M.H., “A Norton equivalent model for nonlinear loads”, LESCOPE
conference, Halifax, Canada, July, 2001.
[3]
R. G.
Harley, “Backpropagation Through Time Algorithm to Estimate Nonlinear Load
Harmonic Currents,” vol. 55, no. 9, pp. 3484–3491, 2008.
[4]
Y. Teng,
“Radial-Basis-Function-Based Neural Network for Harmonic Detection,” vol. 57,
no. 6, pp. 2171–2179, 2010.
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This work is licensed under a: Creative Commons Attribution 4.0 International License
© Granthaalayah 2014-2020. All Rights Reserved.