OPERATION OF THE ABET-2201 POWER CONDITIONING UNIT
Ayhan A. Mutlu, Ph.D., and Mahmud Rahman, Ph.D.
Department of Electrical Engineering, Santa Clara University
500 El Camino Real, Santa Clara, CA 95053
December 12, 2004
1. Introduction
With the advent of electricity and technological breakthroughs, electrical energy has been made
available at a reasonable cost through an elaborate and efficient distribution grid system to
households and businesses alike operating various kinds of appliances that run on electricity.
The local distributors of electrical energy charges the consumers based on the consumers’ rate of
electrical energy consumption called “power” expressed in numbers of thousands of watts, i.e.,
kilowatts (kW). The electrical quantity kW that represents the rate of energy consumed can be
minimized if the circuitry is optimized in a way that there is less “spurious” energy lost. The
ABET 2201 product, if incorporated into the electrical circuit, is able to achieve such
minimization. In addition, the ABET-2201 brings about a number of other benefits to the
consumer without introducing any adverse effects, or "side effects." A good understanding of
various aspects of how electrical power is consumed in a circuit is therefore essential to
understand how this product works. The principle of operation of the ABET-2201, based on
theoretical concepts which are substantiated by measurement evidences, is presented in the
following.
2. Types of loads and their electrical behavior
Theoretically, there are three basic types of loads in an electrical system, e.g., resistive,
inductive, and capacitive. While electrical energy is expended in pure resistive loads, electrical
energy is not expended but stored in ideally inductive and capacitive loads. Although all
practical loads and appliances at a consumer’s site incorporate these three types of ideal loads, it
is appropriate to categorize them as mostly resistive, inductive or capacitive. The following is an
example of common practical loads that are used in a household.
a. Resistive: Oven, light bulbs, iron, electric heaters, etc.
b. Inductive: Appliances with motors and transformers are examples of inductive loads
which include air-conditioners, washers, dryers, refrigerators, induction motor, power
transformer, lighting ballasts, welder or induction furnace, etc.
c. Capacitive: Rechargeable batteries, etc.
Since the currents flowing in inductive and capacitive loads are half a cycle out of phase, it is
possible to make their sum zero at any particular time by adjusting their magnitudes,
consequently reducing the total current magnitude flowing through the Energy-meter (kW-hour
meter) installed by the local distributors to monitor energy consumed by a subscriber. This is the
essence of "power factor correction," where power factor refers to cosine of the phase angle
between the voltage and the total current. The phase angle θ = ωt, where t = time and ω = 2π/T is
the angular frequency of power supply and T = 1/f, where the principle frequency f of the power
being delivered is usually 60 Hz. For purely resistive load, θ = 0o, hence power factor for resistive load = cosine 0o = 1. For purely inductive and capacitive loads, power factor = cosine (±90o) = 0. Power factor correction implies to the situation where the inductive load current is
balanced by capacitive load current thus reducing the total current to a minimum and the phase
angle between the voltage and the total current representing the algebraic sum of the individual
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load currents approaches 0o, i.e., cosine 0o = 1. At lower power factor, the total current is larger
and vice versa.
The current passing through the current coil of the Energy-meter installed by the power
distributor to monitor power consumption is the algebraic aggregate of the individual resistive,
inductive, and capacitive currents flowing in different loads of the household. Power distributors
require the industrial consumers to keep the power factor of the household read at the Energymeter
above say, 0.8, since power factors below 0.8 would require the distributors supply larger
currents, therefore running larger generators which in turn would cost them more. Also, smaller
current associated with higher power factor will minimize various resistive losses in the
distribution system. Therefore, industrial consumers are charged a penalty at a predetermined
rate based on their operating power factor.
The ABET-2201 is capable of correcting the power factor toward various benefits of the
consumer as explained below.
3. The Role of the Capacitor in the Electrical Power System
Capacitor is a device that stores energy in the electric field established between a pair of
conductors on which equal but opposite electric charges have been induced. Historically,
capacitors have taken the form of a pair of thin metal plates, whether flat or tightly coiled up in a
cylinder (like a sushi roll), but every multi-conductor geometry exhibits the phenomenon of
capacitance.
The capacitance of a traditional flat-plate capacitor--and, resultantly, the amount of energy that
can be stored in the capacitor--is proportional to the surface area of the conducting plate and
inversely proportional to the distance between the plates. It is also proportional to the
permittivity of the dielectric substance that separates the plates, whether vacuum, air, or
specially engineered materials chosen for their high electrical permittivity.
In a direct-current (DC) circuit, a capacitor acts like an open circuit: no current flows through it,
though the potential difference initially induced between its conductors can serve as an
exponentially decaying energy source for the circuit. In an alternating-current (AC) circuit, a
capacitor cyclically stores and releases energy at twice the frequency of the forcing source.
3.1. Power Factor Correction
ABET-2201 brings the advantages of the power factor correction capacitor to household use.
Figure 1 shows a typical connection of the ABET unit in a household. This unit is usually
connected to the fuse panel where the electricity is distributed to different locations in the house.
As mentioned above, the current passing through the current coil of the Energy-meter installed
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by the power distributor to monitor power consumption is the algebraic aggregate of the
individual resistive, inductive, and capacitive currents flowing in different loads of the
household, as shown in Fig. 1. Since the currents flowing in inductive and capacitive loads are
half a cycle out of phase, it is possible to make their sum zero at any particular time by adjusting
their magnitudes, consequently reducing the total current magnitude flowing through the Energymeter.
Fig. 1. An example ABET-2201 installation in a typical household.
Figure 2 (a) illustrates the instantaneous supply voltage, and currents in resistive, inductive,
capacitive loads. It can be clearly seen that while the current in the resistive load is in phase with
the supply voltage (θ = 0o), the current through the inductive load lags the supply voltage by a quarter of a cycle (θ = -90o), and the current through the capacitive load leads the supply voltage by a quarter of a cycle (θ = +90o). Figure 2 (b) displays the instantaneous supply voltage and the
total current with and without the ABET-2201 capacitive load. Figure 3 is an exploded view of a
section of Fig. 2 (b) showing clearly the reduction of the phase angle between the supply voltage
and the total current when ABET-2201 is connected to the system, thus improving the power
factor and consequently, reducing the total current magnitude. Due to the reduction in the total
current, the power loss (I2 total x R1) in the resistance R1, between the wattmeter and the ABET-
2201, which varies from house to house, is also reduced. This is the instantaneous power saving
that is achieved by installing the ABET-2201. It is important to note that i) the resistance R1 will
depend on the locations of the Energy-meter and ABET-2201, and ii) the power saving is
proportional to the square of the reduction in the current brought about by the ABET-2201.
Figure 4 presents average voltage, current, power, and power factor measured over a period of
one hour in an actual household. It is clearly observed that the power consumption is reduced
along with the improved power factor and reduced current.
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Fig. 2. (a) Instantaneous voltage and current waveforms of individual components, (b)
Instantaneous voltage and total current waveforms before and after ABET-2201.
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Fig. 3. Phase angle reduction (power factor correction) with the addition of ABET-2201 to the
system. (Circled part of Fig. 2(b) zoomed in.)
236.00
10.66
1785.0 1773.0
0.709
236.00
7.63
1749.0
426.0
0.972
0
1
10
100
1000
10000
Voltage Current (Amp) P (W) Q (VAR) Power Factor
w/o Cap.
w/ Cap.
Fig. 4. Measurement results of average voltage, current, power and power factor in a household.
House Voltage Current (Amp) P (W) Q (VAR) Power Factor
w/o Cap. 236.00 10.66 1785.0 1773.0 0.709
w/ Cap. 236.00 7.63 1749.0 426.0 0.972
% Change 0.00% 28.42% 2.02% 75.97% -36.96%
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3.2 Motor Inrush Current
When the power switch is turned on, a stationary motor acts as short circuit causing a much
higher than normal current to flow. As time passes the magnetic field builds up and the motor
starts to rotate and reaches steady state rpm and the current drops down to normal values. This
high current is called “inrush current” which has minimal impact on the total power consumption
of the motor but may adversely affect motor lifetime by stressing out its wiring. The magnitude
of this current is a function of the motor horsepower and design characteristics.
Our experiments have shown that adding ABET-2201 has reduced the peak inrush current of the
tested motor by about 5%. Also, when the motor was under full load, the unit has reduced the
inrush current time about 15%.
Fig. 5. Motor inrush current with and without ABET-2201 capacitor unit at 1.6 lbf-in
dynamometer load.
3.3. Voltage Sags
The current i, and the voltage V, in a capacitor C, is related to each other by the following
equation,
dV i C
dt
=
where dV dt is the time rate of change of the voltage across the capacitor. Therefore, the voltage
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across the capacitor cannot change instantaneously (i.e., dt = 0) because it will then need an
infinite amount of current to do so. As a consequence, whenever the capacitor is subjected to a
sudden voltage surge or sag, the capacitor tends to reduce it to certain extent depending on its
size. This behavior of capacitors have lead to applications where these are connected in parallel
with the power circuits of most electronic devices and larger systems (such as factories) to shunt
away and conceal voltage and current fluctuations from the primary power source to provide a
"clean" power supply for signal or control circuits. Such effects in capacitors can also be
interpreted to act as a local reserve for the DC power source, to smooth out fluctuations by
charging and discharging each cycle. Figure 6 presents the effects of ABET-2201 capacitor on
voltage sag due to an induction motor switching in a household.
116
117
118
119
120
121
122
123
0 50 100 150 200 250 300
Time (sec.)
Voltage (V)
Line Voltage (With Capacitor)
Line Voltage (No Capacitor)
> 1 V
Fig. 6. The effects of ABET-2201 capacitor on voltage sag due to an induction motor switching
in a household.
3.4. Harmonics and Temperature
Harmonic distortion is the deviation in the waveform of the supply voltage from its ideal
sinusoidal waveform due to inclusion of higher frequency components in addition to the
fundamental frequency. The major adverse effect of the harmonics is heating of induction motors
and transformers in the household leading to reduced lifetime of the motor. It has been known
that a reduction of 10 oC in the operating temperature of a motor essentially doubles its lifetime.
The ABET-2201 in conjunction with the resistance of the household wiring forms a low-pass
filter which prohibits higher frequency components from the incoming supply into household
loads. Consequently, motors are subjected to less heating as illustrated in Fig. 7.
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Motor Temperature
0
10
20
30
40
50
60
0 20 40 60 80
Time (min.)
Temperature (C)
With Capacitor (Tmax=42 C)
No Capacitor (Tmax = 48 C)
Fig. 7. The effect of ABET-2201 capacitor on the temperature of a motor running under
dynamometer load.
4. The power distribution panel installed by distributor
The distributor of electrical energy installs a power distribution panel outside a household so that
their personnel can monitor the total energy consumed by the household by reading the Energymeter
installed in the panel. Two wires with 220 V across them are brought in from the locality
supply grid into the distribution panel. All loads in the house which run on 220 V are connected
across these two wires. Loads which run on 120 V are connected across one of these two wires
and the ground terminal which is fabricated in each household by inserting a solid copper rod
deep into the soil. All 120 V loads are divided into two circuits, each consisting of one the
above mentioned two wires and the ground terminal. Figure 8 shows these two different
configurations.
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Fig. 8. Distribution panel configurations in a household
5. Conclusion
An attempt has been made to elucidate the principle of operation of the ABET-2201 Power
Conditioning Unit in offering significant benefits in the areas of reduced power usage, decreased
motor temperature, improved power factor, reduced inrush current and suppression of voltage
sags. Investigations are being continued to understand and explain other effects that may have
implications on the ABET-2201 such as
i) Harmonics generated in the household loads,
ii) Impact of the unit to the distribution system during non-peak hours (i.e., nights).
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