Power Quality Consideration for Off-Grid Renewable Energy Systems

doi:10.4236/epe.2013.55039

Paper Menu >>

Journal Menu >>

Energy and Power Engineering, 2013, 5, 377-383

http://dx.doi.org/10.4236/epe.2013.55039 Published Online July 2013 (http://www.scirp.org/journal/epe)

Power Quality Consideration for Off-Grid

Renewable Energy Systems

Mojgan Hojabri1, Arash Toudeshki2

1Faculty of Electrical and Electronics Engineering, University Malaysia Pahang (UMP), Pekan, Malaysia

2Department of Electrical and Electronic Engineering, University Putra Malaysia (UPM), Serdang, Malaysia

Email: mojganhojabri@ump.edu.my

Received April 11, 2013; revised May 12, 2013; accepted May 20, 2013

bution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly

cited.

ABSTRACT

Necessity of electricity access in remote area is the main reason for expanding decentralized energy system such as

stand-alone power systems. The best electrical power supply must provide a constant magnitude and frequency voltage.

Therefore, good power quality is an important factor for the reliable operation of electrical loads in a power system.

However, the current drawn by most of electronic devices and non-linear loads are non-sinusoidal, which can result in a

poor power quality, especially in off-grid power systems. Poor power quality is characterized by electrical disturbances

such as transients, sags, swells, harmonics and even interruptions in the power supply. Off-grid power systems world-

wide often struggle with system failures and equipment damage due to poor power quality. In this paper, MAT-

LAB/Simulink is used to model and analyses power quality in an off-grid renewable energy system. The results show

high voltage transient when the inductive loads were switched OFF. The voltage and current harmonics are also deter-

mined and compared for various types of loads.

Keywords: Off-Grid Renewable Energy System; Power Quality; Pulse Width Modulation (PWM) Inverters; Total

Harmonic Distortion; Total Demand Distortion

1. Introduction

Energy demand increasing makes important problems

such as grid instability or even outage. Therefore, more

energy must be generated at the grid. However, energy

generation by big plant is not economically. Moreover,

implementation of distributed generation is rapidly in-

creased. Because of increasing global warming, limita-

tion and high cost of fossil fuel sources, governments

tend to increase use and implementation of renewable

energy sources. The main difference between renewable

energy and fossil fuels systems is up-front cost versus

lifelong energy cost. Currently, in most development

countries, governments as well as utilities provide a vari-

ety of incentives, to help the renewable energy industry

reach to a higher economic scale. Figure 1 shows the

annual growth rates of renewable energies in the world

between 2006 and 2011 [1]. Solar/photovoltaic, wind,

hydro, geothermal, tidal, wave and bio energy are exam-

ples of renewable energy sources which the solar/

photovoltaic and wind are most popular among them.

However, environmental friendly is the principal

advantage of renewable energies, high up-front cost and

uncontrollability are the main disadvantages of it [2].

Renewable energy sources can be used as an off-grid or

on-grid systems. An off-grid renewable energy system is

typically a stand-alone power system located in a remote

area to fulfill residential or commercial power needs.

Because of the high installation price and technical

problems for supplying utility power in remote area, this

type of power system is useful and also isolated from the

power grid system. The main objectives of this paper are

to create a simulation of a typical off-grid system and

study the power quality issues through the simulation.

Moreover, it determines the issues and impacts of poor

power quality issues on various types of linear and

non-linear loads. The organization of this paper follows

the structure of off-grid power system, power quality

considerations, simulation with the concluded remarks.

2. Structure of Off-Grid Power System

A typical off-grid system is shown in Figure 2. As it is

shown in this figure, an off-grid renewable energy

M. HOJABRI, A. TOUDESHKI

378

Figure 1. World average annual growth rates of renewable

energy capacity between 2006-2011 [1].

Figure 2. Block diagram of off-grid renewable energy sys-

tem.

system is included a renewable energy source, charge

controller, battery and inverter. The important of re-

newable energy sources are solar panel, wind turbine,

hydro turbine, diesel or biofuel generator and geothermal

source. Among these renewable energy sources, solar

and wind are more common since their availability.

Photo Voltaic (PV) cells have no moving parts. They

require only sunlight to operate, and do so without

depleting the materials they are made of. PV modules are

encased in strong tempered glass and are tested to

withstand wind, rain, snow, ice and hailstones. After

installation, PV systems generate electricity for decades

at no additional cost while producing no greenhouse

gases. Off-grid systems with higher demand request

might use another energy sources like wind turbine.

Because much more energy is found in faster winds, it is

wise to place wind turbines where the wind is strong,

steady and smooth. Wind turbines placed just above the

ground on a breezy knoll make lovely spinning pieces of

artwork, but they don’t produce much electricity. A good

wind site has consistent, fast wind that pumps genuine

energy into the turbine’s generator for many hours of

every day. Occasional gusty days or steady but light

breezes just don’t cut it.

Charge controller is another component of off-grid

system which is needed to protect the batteries from

over-charging voltage. Off-grid system also needs battery

to provide power when needed. Price and performance,

capacity, cycle life, self-discharge rate, safety, hazards,

requirement maintenance, size and space requirement are

the important features which must be considered to

choose batteries for the system. The heart of the grid-

direct system is a DC to AC inverter which adapts to the

power grid voltage and frequency. Inverter technology

has an important role to have safe and reliable grid in-

terconnection operation of renewable energy systems. It

is also necessary to generate a high quality power to the

grid with reasonable cost [2-5]. Inverters are divided into

three main types: grid-tied inverters, grid-tied inverters

with battery back-up and stand-alone inverters. And also,

inverter control techniques became interesting for power

system researchers [6-8]. The important characteristics of

good off-grid inverters are high efficiency, low standby

losses, low harmonic distortion, easy maintenance and

reliability. Therefore, some standards have been pub-

lished to detect the power quality, grid-connected and

unintentional islanding operation [9-12].

3. Power Quality Considerations

The term “power quality” refers to a wide variety of

electromagnetic phenomena that characterizes voltage

and current waveforms at a given time and at a given

location on the power system [13]. Power quality is used

to describe the electric power that drives an electrical

load and the load’s ability to function properly with that

electric power. In the absence of high quality power,

loads may malfunction, fail prematurely or not operate at

all [14]. The power quality of a system is defined by a

number of parameters, as long-duration, short-duration

voltage variations, harmonic distortion and transients.

Harmonics are current and voltage waveform compo-

nents that represent multiples of the fundamental fre-

quency. Harmonic distortion in an electrical power sys-

tem is the alteration of the original shape or characteris-

tics of the current or voltage waveforms due to the pres-

ence of harmonics. Harmonic distortion is the result of

nonlinear loads and switching power electronic devices

on the system. Some of the problems caused by harmon-

ics include: very high neutral currents, flickering lights,

random tripping of circuit breakers, malfunction of sensi-

tive equipment, fire hazards, reduced power factor,

overheated phase conductors, panels and transformers,

reduced system capacity due to excessive heating, pre-

mature failure of transformers and UPSs. Total Harmonic

Distortion (THD) is used to quantify the presence of

harmonics in a power system. The THD for a voltage

waveform is defined as the ratio of the sum of the voltage

magnitudes of all harmonic components to the voltage

magnitude of the fundamental frequency [15]:

22 2

THD n

VV V







(1)

The harmonic current distortion expressed as a

function of the maximum demand load current using a

M. HOJABRI, A. TOUDESHKI 379

15- or 30-minute demand period is called Total Demand

Distortion (TDD)[16]. The TDD is given by:

TDD

(2)



where

is the maximum demand load current at the

fundamental frequency, measured at the Point of Com-

mon Coupling (PCC) from a 15-minute or 30-minute

billing demand load kW, and

is the square root of

the sum of the squares of the harmonic currents, h

[17].

is given by:

25 2



 (3)

Maintaining a good power quality is important for the

reliable operation of loads. Different power quality stan-

dards are recommended to ensure every piece of equip-

ment operates well with maximum efficiency, without

causing any deterioration of the equipment itself. Voltage

standards are also set by the National Electrical Code

(NEC). According to NEC standards, a maximum volt-

age drop of 5% from the standard voltage is allowed at

the equipment. This 5% voltage drop includes less than

3% voltage drop in a feeder and an addition of less than

3% voltage drop in individual branch circuits [18].

Table 1 specifies the harmonic current limits based on

the size of the load with respect to the size of the power

system to which the load is connected. The ratio Isc/IL is

the ratio of the short-circuit current (Isc) available at the

PCC to the maximum fundamental load current. It is

recommended that the load current, IL, be calculated as

the average current of the maximum demand for the

preceding 12 months. As seen in Table 1, as the size of

the user load decreases with respect to the size of the

system, the percentage of harmonic current that the user

is allowed to inject into the utility system increases. Most

off-grid systems have a low short circuit current and

would fit into the first, most restrictive category of TDD

less than 5 percent.

Table 1. IEEE standard current distortion limits [6].

Isc/IL <20 20 < 50 50 < 100 100 < 1000>1000

H < 11 4 7 10 12 15

11 ≤ h < 17 2 3.5 4.5 5.5 7

17 ≤ h < 23 1.5 2.5 4 5 6

23 ≤ h < 35 6 1 1.5 2 2.5

35 ≤ h 0.3 0.5 0.7 1 1.4

Total Demand

Distortion

(TDD)

5 8 12 15 20

Isc: Maximum Short- Circuit Current

IL: Maximum Demand Load Current

Table 2 specifies the IEEE voltage distortion limit for

utilities. At bus voltages of 69 kV and below, the THD

should not exceed 5% and the individual harmonic dis-

tortion should not be more than 3% at the PCC. However,

a THD well above the recommended maximum may not

be a problem on a distribution circuit if the load demand

is very low. Thus, the IEEE standard has defined TDD

with its standard limits to take this situation into account.

Different power conditioning devices provide essential

protection against power quality problems. All of these

devices provide isolation from the power quality distur-

bance. Power conditioning equipment can include one or

more of the following: surge suppressor, noise filter

harmonic filter, motor-generator set, and dual feeder with

static transfer, isolation transformer, low-voltage line

reactor, Uninterruptible Power Supply (UPS).

4. Simulation Results

A complete Simulink model for an off-grid power system

with a pure sine wave inverter and a motor load is

presented in Figure 3. The major parameters used in this

Simulink model are shown in Table 3. A variable step

discrete with a sampling time of 1 µs was chosen. A

variable step solver shortens the simulation time of a

Simulink model significantly by reducing the number of

steps as necessary, by adjusting the step size for a given

level of accuracy [19]. A switch was placed before the

motor to analyze the motor performance at the instant of

turning OFF and turning ON. A timer set a fixed timing

for the switch to open and close. Scopes were placed to

view the voltage and current waveforms at different

nodes in the circuit.

Characteristics of a 560 W single-phase induction

motor is shown in Figures 4 and 5. The three subplots

represent the voltage waveform, current waveform and

Table 2. IEEE standard voltage distortion limits [6].

Bus Voltage Individual Voltage

Distortion (%)

Total Voltage

Distortion (THD %)

V < 69 kV 3 5

69 kV< V < 161 kV1.5 2.5

161 kV ≤ V 1 1.5

Table 3. Main parameters of Simulink model.

Device Parameters

Battery 24 V

LC Filter Cut-Off Frequency = 100 Hz,

Switching Frequency = 2 kHz

Transformer 4 kVA, 60 Hz, 20:120

Induction Motor 560 W (0.75 hp), 120 V, 60 Hz

M. HOJABRI, A. TOUDESHKI

380

Figure 3. A Simulink model of an off-grid renewable energy

system.

(a)

(b)

(c)

Figure 4. Output load characteristics of motor: (a) Voltage

waveform; (b) Current waveform; and (c) Active and reac-

tive power.

the power for the motor, respectively. When the switch

was turned ON at T = 0.3 of a second, a current of almost

23.5 A was drawn by the motor while maintaining an

output voltage of 117.2 V. A high amount of power

(active power of 2632 W and reactive power of 801 VAR)

was drawn by the motor at that time, compared to its

(a)

(b)

Figure 5. Motor characteristics: (a) Auxiliary winding cur-

nt waveform; and (b) Capacitor voltage.

power rating of 560 W. The current drawn by the motor

started decreasing after the auxiliary winding of the

motor was disconnected (when the motor speed reached

75% of its synchronous speed of 1800 RPM), and the

motor current settled to normal operating current of 3.25

A (Figure 6).

During the operating condition, more reactive power

(375 VAR) was consumed by the motor than the active

power (65 Watts). When the switch was turned OFF at

(65/60)th of a second, the motor experienced a high

voltage transient, the value even reaching 43 kV, due to

the simulated instantaneous change in current.

The simulation results did not show any voltage sag

caused by the induction motor during normal operation,

but it indicated the high current at start up, almost six

times the normal operating current, which was similar to

the actual water pump drawing a start-up current seven

times higher than its normal operating current. The

simulation also predicted a much larger transient at

turn-off due to the idealized instantaneous change in

current. The gate pulses for each inverter switch were

generated by the PWM generator as shown in Figure 6.

Only a pair of switches (S1 and S4) or (S2 and S3) were

turned ON at any instant of time. For example, at 0.035

sec, switches S1 and S4 were ON while S2 and S3 were

OFF. The widths of the generated pulses were varied to

ensure that their averaged output produced a 60 Hz

inusoidal waveform. s

M. HOJABRI, A. TOUDESHKI

381

Figure 6. Gate pulses for inverter switche s S1, S2, S3 and S4.

The higher frequency components in the PWM output

of the pure sine wave inverter were filtered using a low

pass LC filter with cut-off frequency 100 Hz, and then

the resulting sine wave was passed through a step-up

transformer. The primary and secondary voltage wave-

forms of transformer are shown in Figure 7. The peak

value of the primary voltage was close to the battery

voltage. The voltage transients that occurred at the in-

stant of switching OFF the motor load travelled to the

secondary side of the transformer. The secondary wind-

ing of the transformer experienced a voltage transient of

nearly 1640 V on the positive half cycle and −2080 V on

the negative half cycle at 1 sec. The transient voltage,

however, did not travel to the transformer’s primary side

because of its nearly instantaneous duration, the absence

of parasitic capacitance in the secondary winding in the

model, and also because of the absence of a direct physi-

cal connection between the two windings [20].

Using the FFT analysis tool in Simulink, the THD of

the output voltage and current waveforms were recorded.

Figure 8 shows the voltage harmonics for the 560 W

motor supplied by the pure sine wave inverter, in which

case the THD value was 8.34% for normal operation. As

the low pass filter eliminated the low order harmonics

well, some higher order harmonics were still seen, but

with small magnitudes. The THD for the current wave-

form during the normal operating condition was 8.79%

as shown in Figure 9. Both of these THD values were

well above the IEEE standard of 5%. The generation of

harmonic currents is a cause for equipment failure and is,

M. HOJABRI, A. TOUDESHKI

382

(a)

(b)

Figure 7. Secondary and primary voltage waveforms of a

step-up transformer.

Figure 8. Voltage harmonics of an induction motor during

normal operating conditions.

therefore, a serious issue for off-grid systems.

5. Power Quality Analysis for Resistive and

Inductive Loads

The system power quality effects from other devices

were observed by replacing the motor load with a parallel

RL load of different power ratings. The loads were

turned ON at 0.5 sec to allow time for the inverter tran-

sients to settle down, and the loads were turned OFF at

1.08 sec. When the load switch was turned OFF, large

Figure 9. Current harmonics of an induction motor during

normal operating conditions.

voltage transients were seen with the parallel RL load as

they were with the motor load, due to the unrealistic,

instantaneous change in the modeled current. For exam-

ple, voltage transients of 350 kV occurred when an in-

ductive load (500 W and 750 VAR) was used. This volt-

age transient caused a negative voltage transient of mag-

nitude 1100 V at the secondary side of the transformer.

However, there were no transients seen for a purely re-

sistive load, due to its linear relationship with current.

Inductive loads (which are the dominant reactive load in

a residential setting) can therefore be assumed as the

primary source of voltage transients. The simulated in-

stantaneous change in current through the inductor is

responsible for generating this high voltage transient ac-

cording to the relation [21]:

 (4)

where V is voltage induced across the inductor, L, due to

changing current di/dt. High start-up currents are drawn

by the inductive loads to energize their coils. However,

none of the purely resistive loads or loads where active

power dominated the reactive power drew high start-up

currents, as expected. For purely resistive loads, the

simulation results showed that the current and voltage

harmonics decreased slightly with heavy loads. For in-

ductive loads also, voltage harmonics decreased while

the current harmonics increased with heavy loads be-

cause of the high fundamental current draw. Table 4

summarizes the THD of the current and voltage wave-

forms for different simulated loads and the corresponding

voltage transients that appeared in the system. This

simulation shows the off-grid loads had significant cur-

rent and voltage harmonics due to the inverter’s voltage

along with the power electronics used in those loads. So

the load’s voltage and current harmonic distortion in-

crease by increasing the pure resistance load. For induc-

M. HOJABRI, A. TOUDESHKI

383

Table 4. Simulation results for current and voltage har-

monics for different loads.

Load Voltage THD% Current THD %

No Load 7.45 -

150 W 7.68 7.68

500 W 8.17 8.17

700 W 8.56 8.56

100 W, 200 VAR 7.63 3.68

300 W, 500 VAR 7.87 3.91

500 W, 1000 VAR 8.18 3.93

tive loads, the total current harmonic distortion is in

IEEE standard range. But the voltage THD is out of

IEEE standard range (more than 5%).

6. Conclusion

In most cases, off-grid renewable energy systems are

cheaper than extending the power grid to provide elec-

tricity for remote areas. Therefore, most countries are

developing aims for electrification that includes renew-

able off-grid options and/or renewably powered mini-

grids. However, good power quality is an important fac-

tor for the reliable operation of this system. In this paper,

the MATLAB/Simulink software was used to model and

analyze power quality for additional configurations of the

typical off-grid system. The simulation results show the

high voltage transient and high start-up current for induc-

tive loads. Moreover, the results show the total harmonic

distortion of current and voltage for pure resistance loads

is significant. However, for inductive load, total demand

distortion is in the acceptable range (less than 5%), but

the total harmonic distortion of voltage is still more than

IEEE standard limitation.

REFERENCES

[1] Global Status Report, “Renewable Energy Policy Net-

work for the 21st Century,” Renewables, Paris, 2012.

[2] M. Hojabri, A. Z. Ahmad, A. Toudeshki and M. Sohei-

lirad, “An Overview on Current Control Techniques for

Grid Connected Renewable Energy Systems,” 2nd Inter-

national Conference on Power and Energy Systems

(ICPES), November 2012, pp. 119-126.

[3] J. H. R. Enslin and P. J. M. Heskes, “Harmonic Interac-

tion between a Large Number of Distributed Power In-

verters and the Distribution Network,” IEEE Transactions

on Power Electronics, Vol. 19, No. 6, 2004, pp. 1586-

1593.

[4] A. Bhowmik, A. Maitra, S. M. Halpin and J. E Schatz,

“Determination of Allowable Penetration Levels of Dis-

tributed Generation Re-Sources Based on Harmonic Limit

Considerations,” IEEE Transactions on Power Delivery,

Vol. 18, No. 2, 2003, pp. 619-624.

[5] IEEE Standard 1547-2003, “IEEE Standard for Intercon-

necting Distributed Resources with Electric Power Sys-

tems,” 2003, pp. 0_1-16.

[6] H. L. Jou, W. J. Chiang and J. C. Wu, “A Simplified Con-

trol Method for the Grid-Connected Inverter with the

Function of Islanding Detection,” IEEE Transactions on

Power Electronics, Vol. 23, No. 6, 2008, pp. 2775-2783.

[7] M. Dai, M. N. Marwali, J. W. Jung and A. Keyhani, “A

Three-Phase Four-Wire Inverter Control Technique for a

Single Distributed Generation Unit In Island Mode,”

IEEE Transactions on Power Electronics, Vol. 23, No. 1,

2008, pp. 322-331.

[8] Q. Zhang, L. Qian, C. Zhang and D. Cartes, “Study on

Grid Connected Inverter Used in High Power Wind Gen-

eration System,” 41st IAS Annual Meeting, Industry Ap-

plications Conference, Tampa, 8-12 October 2006, pp.

1053-1058.

[9] IEEE Standard 929-2000, “IEEE Recommended Practice

for Utility Interface of Photovoltaic (PV) Systems,” 2000.

[10] IEEE Standard Conformance Test Procedures for Equip-

ment Inter-Connecting Distributed Resources with Elec-

tric Power Systems 1547. 1-2005, IEEE P1547.1.

[11] DIN VDE 0126-1-1, “Automatic Disconnection Device

between a Generator and the Public Low-Voltage Grid,”

1999.

[12] Grid Code, “High and Extra High Voltage,” E.ON, Lou-

isville, 2003.

[13] A. Moreno-Muñoz, “Power Quality: Mitigation Tech-

nologies in a Distributed Environment,” Springer-Verlag

London limited, London, 2007.

[14] M. K. Saini and R. Kapoor, “Classification of Power

Quality Events—A Review,” International Journal of

Electrical Power & Energy Systems, Vol. 43, No. 1, 2012,

pp. 11-19.

[15] G. R Slone, “The Audiophile’s Project Sourcebook: 120

High-Performance Audio Electronics Projects,” TAB

Electronics, New York, 2001.

[16] IEEE Standard 519-1992, “IEEE Recommended Practices

and Requirements for Harmonic Control in Electrical

Power Systems,” 1993.

[17] L.A. Schienbein and J.G DeSteese, “Distributed Energy

Re-Sources, Power Quality and Reliability-Background,”

Pacific Northwest National Labratory, Richland, 2002.

[18] ANSI C84.1-2011, “American National Standard for

Electric Power Systems and Equipment—Voltage Ratings

(60 Hertz),” 2011.

[19] MathWorks, “Product Documentatio Choosing a Solver,”

MathWorks, 2012.

http://www.mathworks.com/help/toolbox/simulink/ug/f11

-69449.html

[20] ANSI C84.1-2011, “American National Standard for

Electric Power Systems and Equipment Voltage Ratings

(60 Hertz),” 2011.

[21] MathWorks Products, “Choose a Solver,” Docu-

mentation Center, 2013.

http://www.mathworks.com/help/gads/choosing-a-s

olver.html