Double Revolving field theory-how the rotor develops torque
Sapf2
1. SHUNT ACTIVE
POWER FILTERS
Under supervision of : Submitted By:
Mrs. Manjima Bhattacharya Shivangni sharma
(Dept. of Electrical Engg.) 15EE221
NIT PATNA M.Tech-PhD DD,POWER SYSTEM
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3. INTRODUCTION
In these days use of non linear loads
has increased since the advancement
and easy controllability in electrical
power.
This results in generation of current
harmonics and reactive power in
system network.
Harmonics has several negative
effects.
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4. HARMONICS?
Harmonics are the components where the frequency is an
integral multiple of fundamental frequency
Harmonic distortion is measured by calculating
THD(Total harmonic distortion)
where I stands for current , h for harmonics
According to IEEE Std 519-1992,current THD has to be
less than 5%
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5. EFFECTS AND It’s SOLUTIONS
Harmonics can cause
Overheating
Voltage Distortion and Flickering
Interference
Different solutions are
Capacitors
Compensators
Passive filters
Active filters
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6. FILTERS
Active Power Filters
1.Series Active Power Filter
• SeAPF is connected in series with the T.L
• Acts as a controlled voltage source
2.Shunt Active Power filter
• ShAPF is connected in parallel with the T.L
• Acts as a controlled current source
3.Unified power quality controller
• Combination of passive ,series and shunt filters
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7. SHUNT ACTIVE POWER
FILTER
The principle of the shunt filter is to produce harmonic
currents equal in magnitude but opposite in-phase to those
harmonics that are present in the grid.
Phase shift of the harmonic current is 180 degrees
SAPF is a closed loop structure
SAPF can compensate reactive power and can also
mitigate harmonics and distortions
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10. ANALYSIS TECHNIQUES
Reference generation techniques
To compensate harmonics , it is important to generate
compensating current reference
P-Q theory
Others includes dq0 , ANN..etc.
Tracking Methodology
To track reference current properly
Hysteresis controller , PI controller , slide mode controller etc.
Converter Topology
Depending on type of loads , voltage…,performance indices
Such as ,THD ,efficiency , cost , reliability
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11. DIFFERENT BLOCKS IN
SAPF
Instantaneous power calculation block
Power compensation
Reference current calculation block
PWM converter
DC voltage regulator
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12. INSTANTANEOUS POWER
CALCULATION
The crucial part of SAPF which calculates the
compensation currents
These currents are calculates using “P-Q theory.”
This Constant power control strategy was the first strategy
developed for Active power filters by Akagi et al. in 1983
This theory uses Clarke’s transformation which consists of
real matrix that transform three phase ‘V’ or ‘I’ into αβ0
stationary reference frames.
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13. CLARKE’S TRANSFORMATION
AND IT’S INVERSE
• For a 3-phase system without a neutral/ground, we can neglect the zero sequence
component to make the matrices as
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14. CONTINUED…..
Using the Clarke’s transformation we can convert the
current and voltages into αβ frame and again back to abc
by inverse Clarke’s transformation
We separate the apparent power into real and imaginary
parts using P-Q theory
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15. AVERAGE AND OSCILLATING
COMPONENTS
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•Mean value of instantaneous real power that is transferred from
source to load in a balanced way through abc coordinate . This is
the fundamental energy source to load.
•Alternating value of Instantaneous real power which is
exchanged between power source and load . As this not
contribute in energy transfer , this component must be
compensated . This is due to harmonic currents.
•Mean value of instantaneous Imaginary power exchanged
between source and load . Choice of compensation of this power
depends upon requirements . This is due to fundamental reactive
current.
•Average value of instantaneous imaginary power exchanged
between phases and load . This is also must be compensated.
16. These currents
and voltages
are taken as
inputs to the
filter from the
line or load.
Through
transformatio
n, we get the
real and
imaginary
power values
The power to be
compensated must
be selected i.e. 𝒑 etc.
The powers to be
compensated are given
input. The compensator
should draw exactly the
given amount of current
that produces the inverse
of powers that are drawn
by the load.
By applying Inverse
Clarke's
transformation, we
get the actual abc
coordinates which
can be applied to the
line again.
ACTUAL IMPLEMENTATION
OF P-Q THEORY IN SAPF
17. PWM CONVERTER
Responsible for power processing.
Consists of VSC or CSC , To force the PWM converter act
as a controlled voltage or current source
VSC is made up of PE devices(GTO, IGBT…)
PE devices are fired based on the APF currents
APF currents can be calculated using Hysteresis
Controller method. 17
18. HYSTERESIS CONTROLLER
Control the VSI through the PWM in a manner that the
output current of inverter then tries to track the reference
current fed to the hysteresis current controller which
works in a close loop
A reference value is kept and is compared with the two
input of the controller
Based on the error between the 2 inputs and the reference
value, signals are generated
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20. DC VOLTAGE REGULATOR
Determines the extra amount of power Ploss that causes an
additional flow of energy.
This active power Ploss is then summed up to together
with are passed to calculation of reference current block
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21. ADVANTAGES
Widely compensated harmonic spectrum
Only one filter needed to eliminate all the unwanted
harmonics
Improved stability of the power system due to the lack of
parallel resonance
Its performance is dynamic and take into account the
changes in load
It may also be programmed to eliminate specific number
of harmonics
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22. DISADVANTAGES
This method is poor in compensation of harmonic
current if source voltages are not symmetrical.
Instantaneous reactive power based approaches
require Large number of voltage and current
transducers
Switching frequency of hysteresis controller is not
constant
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24. CONCLUSION
This method utilizes the P-Q theory to detect harmonic
wave and reactive load current efficiently, compensate the
harmonics and reducing the THD value
This method is very important; it allows harmonic
currents and reactive power compensation simultaneously
It injects compensation current in order to cancel the
harmonic component of load . So the source sees the N-L
load in parallel to APF together as an ideal resistor
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25. REFERENCES
A. Bhattacharya, C. Chakraborty and S. Bhattacharya,
“Current compensation in shunt type active power filters,”
IEEE Industrial Electronics Magazine, vol.3, no.3, pp.38-
49, 2009.
H. Akagi, “Utility applications of power electronics ” in
Conf. Proceedings of IPEC Yokohama 95, pp 19-22,1995.
H. Akagi, “Trend in Active Power Line Conditioners ” in
IEEE Trans. On Ind. Electronics, Vol.9, N°3, pp. 263-268,
August 1994.
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