Carbon Emissions Reduction and Power Losses Saving besides Voltage Profiles Improvement Using Micro Grids

doi:10.4236/lce.2010.11001

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Low Carbon Economy, 2010, 1, 1-7

doi:10.4236/lce.2010.11001 Published Online September 2010 (http://www.SciRP.org/journal/lce)

Carbon Emissions Reduction and Power Losses

Saving besides Voltage Profiles Improvement

Using Micro Grids

Rashad M. Kamel, Aymen Chaouachi, Ken Nagasaka

Environmental Energy Engineering, Department of Electronics & Information Engineering, Tokyo University of Agriculture and

Technology, Tokyo, Japan.

Email: r_m_kamel@yahoo.com, a.chaouachi@gmail.com, bahman@cc.tuat.ac.jp

Received July 21st, 2010; revised August 27th, 2010; accepted August 27th, 2010.

ABSTRACT

The objective of this paper is to evaluate the value of enhancement in voltage, amount of emission reduction and

amount of power losses saving with using micro grids. The paper is divided in two parts, the first part evaluates the

voltage improvement and power losses saving with micro (μ) sources (distributed generators like fuel cell, micro tur-

bine, solar cell, wind turbine etc.). The obtained results indicate that using μ sources reduce voltage drop by about 3%,

Also, it is found that using μ sources can reduce the power losses to more than one third of its value without using μ

sources. The voltage at the buses near the μ sources location will suffer from small drop than the buses far from μ

sources locations. The second part calculates amount of CO2, SO2, NOx and particulate matters emissions from main

grid and from μ sources which forms micro grid. The results indicates that more penetration of μ sources in the power

systems especially the renewable sources (solar and wind) will help in reducing or removing emission problems and

solve the green house gas problems. Finally this paper proved with calculations that the micro grid can solve most of

the problems which facing the conventional power system and keep the surrounding environment clean from pollution

and the micro grid will be the future power system.

Keywords: Micro Grid, Voltage Enhancement, Losses Saving, CO2, SO2, NOx and Particulate Matter Emissions

1. Introduction

Increasing penetration of distributed generation (DG)

resources to the low voltage (LV) grids, such as Photo-

voltics, CHP micro-turbines, small wind turbines areas

and possibly fuel cells, alters the traditional operating

principle of the grids. A particularly promising aspect,

related to the proliferation of small-scale decentralized

generations (μ sources), is the possibility for parts of the

network comprising sufficient generating resources to

operate in isolation from the main grid, in a deliberate

and controlled way. These are called micro grids and the

study and development of technology to permit their ef-

ficient operation has started with a great momentum

[1-3].

With the efficient integration of small scale distributed

generation into LV system and ability of supplying its own

local demand customers, exporting energy to neighbor’s

systems and providing ancillary services (flow manage-

ment, voltage and frequency control capabilities) to the

public systems, the development of micro grids has po-

tential to bring a number of benefits into the system in

term of [4]:

 Enabling development of sustainable and green elec-

tricity: Clearly, electricity generated by renewable energy

sources can substitute electricity supplied by conven-

tional power plants with many benefits such as carbon

emission reduction, reducing dependency on depleting

fossil sources and sustainable and “free” energy sources

which in the long term brings lower energy prices.

 Enabling larger public participation in the invest-

ment of small scale generation: Economic appraisal for

installing micro generation will likely require less com-

plex analysis in contrast to large generation. With much

smaller magnitude in the investment, and less complexity

in trading electricity, the financial risks exposed to the

investors are much lower. At a domestic level, the deci-

sion to invest in such generation may be less motivated

by financial gain and influenced by Individual’s will to

2 Carbon Emissions Reduction and Power Losses Saving besides Voltage Profiles Improvement Using Micro Grids

contribute for clean environment. This will clearly enable

larger public participation in contributing to the deploy-

ment of Renewable Energy Sources (RES) in the form of

micro generation.

 Reduction in marginal central power plants: Micro

generation can displace the capacity of peak load or mar-

ginal central power plants.

 Improved security of supply: With a considerable

large number of installed micro generation, the total gen-

eration margin increases. This will also directly increase

the available capacity of supplying peak load condition.

 With a large number of generators, failure in a

number of small generators will not have a considerable

impact on the capability of supplying the demand. This is

in contrast to systems which rely on a relatively small

number of big generators. A failure of one large genera-

tor may cause significant generation deficit and may lead

to load shedding. Micro generation technologies also

bring more diversity in the types of fuel that can be used

to generate electricity. This is likely to increase the secu-

rity of supply and reduce dependency on a particular type

of fuel [5,6].

 Reduction of losses: Currently, losses in a system

which primarily relies on central generation are typically

around 7%-10% of total electricity consumption per year

[4]. The magnitude of losses is influenced by many factors

such as the proximity of generation to loads, circuit im-

pedances, loads, and profiles of loading in each circuit

among others. Bearing in mind that losses are a quadratic

function of the current, the largest losses occur during

peak loading conditions of the circuit. As micro grid is

able to supply its loads locally, it reduces the amount of

power transfer from remote generation via transmission

and distribution circuits. Hence, it will reduce system

losses. This also leads to the reduction of total energy

produced by central power plants. Thus, it will also re-

duce Pollutants (CO2, NOx, SO2 and other particulate

matter) from these plants.

 Enabling better network congestion management

and control for improving power quality: The introduc-

tion of micro generation in the LV networks will provide

better capability of controlling power flows from the LV

systems to the upper voltage networks. Hence, it may

avoid the need for reinforcing the networks due to net-

work congestion or voltage problems.

Based on the previous discussion, using micro grid

will help on voltage improvement, emission reduction

and power losses saving. Many papers discussed the ef-

fect of micro grid on voltage improvement, power losses

reduction and emission reduction, but quantifying

amount of improvement or reduction is not considered.

The main goal of this paper is to evaluate the effect of

the micro grid on voltage enhancement, emission reduc-

tion and losses saving. To conduct the proposed studies,

the benchmark networks used for analysis and its data are

described in Section 2 [single feeder and multi feeder

networks]. Section 3 presents the daily load curves of the

one feeder network (residential load) and three feeders

network with three types of loads (residential, industrial

and commercial loads). Section 4 shows the effect of the

micro grid on voltage improvement and power losses

saving for single feeder and multi feeders networks.

Amount of emission reduction due to using micro grid is

given in Section 5. Conclusions are stated in Section 6.

2. Benchmark Network Used for Analysis

Bench mark network described in references [3] and [7] is

used for analysis. Single line diagram with all buses

marked is shown at the end of the paper (Figure 12). One

feeder network includes 7 buses (buses 1-7) represent the

residential loads. Industrial load (bus 8) represents the

second feeder. The remaining buses (buses 9-16) feed

commercial loads and represent the third feeder. Imped-

ance of the network lines, data for μ sources used and

renewable power time-series used [output KW/Installed

KW] are given in Tables 1-3 respectively [7].

The units have been calculated in power base of 100

KVA and voltage base 400V. Bus 0 represents the main

grid (distribution network).

Micro turbine is located at bus 7, fuel cell is located at

bus 6, and PV3 is located at bus 5 while wind turbine and

PV2-5 are connected to bus 4.

3. Daily Load Curves for Single and

Multiple Feeders Networks

Aggregate daily load curves for single feeder (residential

loads) and three feeders (residential, industrial and com-

Table 1. Line data for micro grid.

Sending BusReceiving

Bus R (p.u.) X (p.u.)

0.0025

0.0001

0.0125

0.021875

0.033125

0.0075

0.015

0.02125

0.010625

0.023125

0.01

0.0001

0.00375

0.004375

0.00875

0.005

0.010625

0.005625

0.00625

Carbon Emissions Reduction and Power Losses Saving besides Voltage Profiles Improvement Using Micro Grids3

Table 2. Data of the used μ sources.

Unit ID Unit Name

Minimum

capacity

(KW)

Maximum

capacity

(KW)

Micro tur-

bine

Fuel cell

Wind

PV1

PV2

PV3

PV4

PV5

0.1

0.05

2.5

Table 3. Renewable power time-series (Output KW/Installed

KW).

Hour Wind

Power

PV-time

series Hour Wind

Power

PV-time

series

0.364

0.267

0.234

0.312

0.329

0.476

0.477

0.424

0.381

0.459

0.39

0.002

0.008

0.035

0.1

0.23

0.233

0.494

0.355

0.433

0.321

0.329

0.303

0.364

0.373

0.26

0.338

0.312

0.346

0.318

0.433

0.37

0.403

0.33

0.238

0.133

0.043

0.003

mercial loads) are shown in Figure 1.

4. Voltage Enhancement and Power Losses

Saving Evaluation with Using Micro Grid

Load flow program [8] is used to calculate the voltages at

all nodes of the micro grid. Results are shown in Figures

2-7. The power factor is 0.85 lagging for residential and

commercial consumers and 0.9 for the industrial ones.

All calculations have been made at p.u of base Vbase =

400 V and Sbase = 100 KVA. The network data are pre-

sented in Sections 2 and 3. It has also been assumed that

in the μ sources the power electronic interface has been

adjusted to give or absorb zero reactive power at all

buses except fuel cell and micro turbine buses. At all

time, we assume that the micro turbine and fuel cell op-

erated at 84% of their maximum capacity (25 KW), and

the renewable sources outputs powers as listed in Table

3. The dashed lines represent results without μ sources

while the solid lines represent results with using μ

sources.

From the above results the following points can be

raised:

 With using μ sources, in the two studied cases (sin-

gle feeder and three feeder), the voltages at all buses are

improved.

 Amount of improvement in case of single feeder

network is better than three feeder case because amount

2 4 6 810 12 14 1618 20 22 24

100

120

140

160

180

200

Hou

Power( KW )

One feeder

Three feeder

Figure 1. Daily load curves for one feeder and three feeders

networks.

510 1520

0. 96

0. 98

1. 02

Hour

Voltage ( pu )

Main grid

510 15 20

0. 96

0. 98

1. 02

Hour

Voltage( pu )

Bus# 1

510 1520

0. 96

0. 98

1. 02

Hour

Voltage( pu )

Bus# 2

510 15 20

0. 96

0. 98

1. 02

Hour

Voltage( pu )

Bus# 3

Figure 2. Voltage at buses 1, 2, 3 and main grid for single

feeder network with and without using μ sources.

510 15 20

0.96

0.98

1.02

Hour

Voltage( pu )

Bus# 4

510 15 20

0. 96

0. 98

1. 02

Hour

Voltage( pu )

Bus# 5

510 15 20

0.96

0.98

1.02

Hour

Voltage( pu )

Bus# 6

510 15 20

0. 96

0. 98

1. 02

Hour

Voltage( pu )

Bus# 7

Figure 3. Voltage of buses 4, 5, 6 and 7 for single feeder

network with and without using μ sources.

4 Carbon Emissions Reduction and Power Losses Saving besides Voltage Profiles Improvement Using Micro Grids

510 1520

0. 96

0. 98

Hour

Voltage ( pu )

Bus# 1

510 15 20

0. 96

0. 98

Hour

Voltage( pu )

Bus# 2

510 1520

0. 96

0. 98

Hour

Voltage( pu )

Bus# 3

510 15 20

0. 96

0. 98

Hour

Voltage( pu )

Bus# 4

Figure 4. Voltage of buses 1, 2, 3 and 4 for three feeder

network with and without using μ sources.

510 15 20

0.96

0.98

1.02

Hour

Voltage( pu )

Bus# 5

510 15 20

0.96

0.98

1.02

Hour

Voltage( pu )

Bus# 6

510 15 20

0.96

0.98

1.02

Hour

Voltage( pu )

Bus# 7

510 15 20

0.96

0.98

1.02

Hour

Voltage( pu )

Bus# 8

Figure 5. Voltage at buses 5, 6, 7 and 8 for three feeder

network with and without using μ sources.

5101520

0. 96

0. 98

1. 02

Hour

Voltage( pu )

Bus# 9

510 15 20

0. 96

0. 98

1. 02

Hour

Voltage( pu )

Bus# 10

5101520

0. 96

0. 98

1. 02

Hour

Voltage( pu )

Bus# 11

510 15 20

0. 96

0. 98

1. 02

Hour

Voltage( pu )

Bus# 12

Figure 6. Voltage at buses 9, 10, 11 and 12 for three feeder

network with and without using μ sources.

510 1520

0. 96

0. 98

1. 02

Hour

Voltage( pu )

Bus# 13

510 1520

0. 96

0. 98

1. 02

Hour

Voltage( pu )

Bus# 14

510 1520

0. 96

0. 98

1. 02

Hour

Voltage( pu )

Bus# 15

510 1520

0. 96

0. 98

1. 02

Hour

Voltage( pu )

Bus# 16

Figure 7. Voltage of buses 13, 14, 15 and 16 for three feeder

network with and without using μ sources.

of power produced by the μ sources is less than the

power demand by loads of the three feeder, also the μ

sources are far from loads of industrial (bus 8) and com-

mercial (buses 9-16) feeders.

 The largest drop of the voltage is about 4.5% with-

out μ sources, because we assume that the voltage at the

main grid (distribution network) equal to 1 p.u., if we

assume that the voltage at the distribution network less

than 1 p.u (due to voltage drop in the transmission net-

work) as actually occur, the voltage drop without using μ

sources will be more than 4% and may be reach to 8%.

The total power losses for one feeder and three feeder

networks at the same conditions mentioned before are

evaluated and the results are shown in Figures 8 and 9.

From the above figures, the following points can be

summarized:

 The total power losses with using μ sources is less

than the losses when μ sources are not used, because us-

ing μ sources reduces the distance between the load and

generation and also, reduce the current flowing from the

main grid. In addition, in our analysis, we calculated the

losses in the transformer which connect the main grid

with the micro grid network. If we take the losses in the

upper distribution and transmission networks, the amount

of losses will exceed the calculated value.

 For single feeder network, at lightly load μ sources

production will feeds the load and export the remaining

power to the distribution grid which make the losses with

using μ sources larger than losses without μ sources.

5. Emission Reduction Evaluation with

Using μ Sources

In order to evaluate the potential of environmental bene-

fits from the micro grids, data about the emissions from

Carbon Emissions Reduction and Power Losses Saving besides Voltage Profiles Improvement Using Micro Grids5

05 10 15 20 25

0. 5

1. 5

2. 5

Hour

Power losses (KW)

with micro sources

without micro sources

Figure 8. Total losses for single feeder network with and

without μ sources.

05 10 15 20 25

Hou

Power losses ( KW )

with micro sources

without micro sources

Figure 9. Total losses for three feeders network with and

without μ sources.

the main grid and data about the emissions of the μ sources

should be taken into account. The emissions for which

calculations are made are: CO2, SO2, NOx and particulate

matters.

5.1. Emissions of the Main Grid

The production of the μ sources displaces power from the

main grid. Thus the emissions avoided are an average

value of the main grid emissions multiplied by the pro-

duction of the μ sources. In our study, typical values of

emissions have been used as shown in Table 4 [7].

Table 4. Typical values of emissions from the main grid.

Pollutants gr/KWh

CO2

SO2

NOx

Particulate Matters

889

1.8

1.6

0.501

5.2. Impact of μ Sources

From the installed μ sources the ones that consume fuels

have emissions which are significantly lower than the

ones in the main grid. Where as the renewable such as

wind and solar energies have zero emissions in their op-

eration. It is assumed that the fuel burned by the Micro

turbine and the fuel cells is natural gas. Table 5 gives the

data used for our analysis [7].

5.3. Results and Discussions

Amounts of emissions with and without using μ sources

for single feeder and three feeder networks are shown in

Figures 10 and 11.

According to the results obtained in the previous fig-

ures the following point can be summarized:

 Using μ sources has large effect in reducing the

amount of emissions on CO2, SO2, NOx and particulate

matters, but the reduction in SO2, NOx and particulate

matters is greater in percentage than CO2 reduction due

to the fact that the fuel burning units use natural gas that

has lower emission levels in particulate matters, NOx and

SO2 compared to thermal stations that use Heavy Oil.

Table 5. Typical emission data for μ sources.

Unit nameCO2 coeff.

(gr/KWh)

NOX coeff.

(gr/KWh)

SO2 coeff.

(gr/KWh)

Parti.

Matters

(gr/KWh)

Micro

Turbine

Fuel Cell

Wind1

PV1

PV2

PV3

PV4

PV5

724.6

489

0.2

0.01

0.004

0.003

0.041

0.001

010 20 30

100

Hour

CO2 emissions( Kg )

010 20 30

100

150

200

Hour

SO2 emissions ( gr )

010 20 30

100

150

Hour

NOX emissions ( gr )

010 20 30

Hour

Particulate Matters emissions ( gr )

SO2 emissions (gr)

CO2 emissions (Kg)

OX emissions (gr)

Figure 10. Amount of CO2, SO2, NOx and particulate mat-

ters emissions for one feeder network with and without μ

sources.

6 Carbon Emissions Reduction and Power Losses Saving besides Voltage Profiles Improvement Using Micro Grids

010 20 30

100

150

200

Hour

CO2 emission( Kg )

010 20 30

100

200

300

400

Hour

SO2 emission ( gr )

SO2 emissions

)

010 20 30

100

200

300

400

Hour

NOX emission ( gr )

010 20 30

100

Hour

Particulate matters emission ( gr )

Figure 11. Amount of CO2, SO2, NOx and particulate mat-

ters emissions for three feeder network with and without μ

sources.

 In our study, the amount of power produced by re-

newable energy is small (15% of the μ sources power), if

the renewable sources increases, amount of emissions

reduction will be more than the value shown in the pre-

vious figures.

CO2 emissions

(

6. Conclusions

Distributed generation (DG) operation can improve the

voltage profile in the micro grid nodes especially at the

feeder where μ sources are installed. Therefore the in-

stallation of DG sources seems to be a solution in im-

proving the voltage profile within a micro grid during

times of low voltages (peak loads). It is found that when

the power produced by μ sources sufficient to loads, the

voltage drop at all buses has a negligible values, also,

using micro grid will decrease the amount of power

losses because the power which produced by μ sources

will consumed locally with the load near from the μ

OX emissions (gr)

Figure 12. Single line diagram for three feeder network.

Current Distortion Evaluation in Traction 4Q Constant Switching Frequency Converters 7

sources which prevent current from flowing or circulat-

ing in the networks transmission lines. Results showed

that using μ sources has more effects in reducing all

types of emissions especially when the μ sources contains

many renewable sources such as wind and solar energy

sources. The authors next step research aims to study the

effects of micro grid in the dynamic performance of the

main grid and how to use the μ sources to solve some of

power system dynamic problems such as voltage stability,

power quality and power system reliability.

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