A practical biogas based energy neutral home system for rural communities of Bangladesh


A practical biogas based energy neutral home system for rural communities of
Bangladesh
C. K. Das, M. A. Ehsan, M. A. Kader, M. J. Alam, and GM Shafiullah 
 
Citation: Journal of Renewable and Sustainable Energy 8, 023101 (2016); doi: 10.1063/1.4942783 
View online: http://dx.doi.org/10.1063/1.4942783 
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A practical biogas based energy neutral home system
for rural communities of Bangladesh

C. K. Das,
1,a)

M. A. Ehsan,
1,b)

M. A. Kader,
2

M. J. Alam,
3

and GM Shafiullah
4

1Department of Electrical and Electronic Engineering, Chittagong University of
Engineering and Technology, Chittagong 4349, Bangladesh
2Department of Electrical and Electronic Engineering, International Islamic University
Chittagong, Chittagong 4203, Bangladesh
3Department of Electrical and Electronic Engineering, Bangladesh University of
Engineering and Technology, Dhaka 1000, Bangladesh
4Department of Electrical Engineering, Energy and Physics, School of Engineering and
Information Technology, Murdoch University, Murdoch, Western Australia 6150, Australia

(Received 27 June 2015; accepted 12 February 2016; published online 2 March 2016;
publisher error corrected 15 March 2016)

Growing demand of energy consumption, subsequent increase in energy generation

costs, and increased greenhouse gas (GHG) emissions, as well as global warming

from the conventional energy sources, encourages interest worldwide to bring a

higher percentage of renewable energy sources such as biogas into the energy mix

to build a climate friendly environment for the future. Moreover, due to high

investment and maintenance costs, governments are not providing enough support

for grid extension and delivering electricity to remote locations or rural areas, in

particular, in under-developing countries like Bangladesh. Therefore, this paper

presents an Energy Neutral Home System (ENHS) that can meet all its energy

requirements from low-cost, locally available, nonpolluting biogas generated from

animal waste, in particular, chicken and cow manure. The proposed ENHS has

been developed for rural community, typically an area of 200 families, and will not

only provide cooking gas and sustainable and affordable power supply to the

community with low emissions, but will also facilitate high quality fertilizer for

agricultural purposes. In-depth analysis clearly demonstrates that the proposed

ENHS not only offers electricity and cooking gas to the community with the lowest

costs, but also reduces the energy crisis and GHG emissions and can play an active

role in developing socio-economic infrastructure of rural communities in

Bangladesh in many ways. VC 2016 AIP Publishing LLC.
[http://dx.doi.org/10.1063/1.4942783]

I. INTRODUCTION

Energy demands are increasing at unprecedented rates worldwide in both developed and

developing countries, already reaching formidable levels. The lack of the ready energy avail-

ability to meet these demands causes inevitable disparity between people and nations globally.

Around the world, 1.3�109 people or roughly a quarter of the global population have no
access to reliable electricity.

1
Most of the rural areas that are far from the mainland or city and

Islands lack access to modern facilities as well as energy services, which have to be considered

as a significant global development challenge today. Reliable and continuous electricity supply

is required for economic development of the communities as well as delivery of key public

services, including health, education, and infrastructure. Moreover, energy is currently being

generated mainly from fossil fuelled power generation that contributes greenhouse gas (GHG)

a)
Author to whom correspondence should be addressed. Electronic mail: choton46@gmail.com. Mobile: þ61-406965280

b)
Electronic mail: amimul66@gmail.com

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emissions into the atmosphere causing changes in global climate condition. These impacts

include land, water, and air pollution, widespread habitat annihilation, along with swelling evi-

dence of links between fossil fuel use and climate change due to global warming.
2–4

Augmented concern about global warming, acid rain, and air pollution has rejuvenated

attention in the application of renewable energy (RE) resources,
5

which has started to be used

as a panacea for solving climate change and also reducing the energy crisis worldwide. Among

all renewable sources, bioenergy is estimated to be the fourth largest resource in the world.
6

Biogas is one of the major categories of an exploitable form with huge biopotential, and it can

be produced from almost all kinds of waste sources.
7

There have been colossal researches on

biogas production and plant efficiency, so the present key research factor is optimization of

biogas systems.
8

In one research paper, operational aspects of two large industrial anaerobic digestion (AD)

amenities and their performances for two years of operation are discussed, which indicates that

proper monitoring and management can increase biogas production by 40%,
9

but the system is

implemented only for urban areas.

The technical and economic performance of an anaerobic digestion family size biogas plant

(15 m
3

volume) installed in Turkey is investigated in a study which corroborates that the lowest

Pay Back Time (PBT) is 3.92 years considering the retailing price of natural gas and solid

fertilizer follow the Turkish market rates of e0.256/m
3

and e180/t, respectively. It is concluded

from the research that the PBT will decreases even more if Energy Maize (EM) utilization rates

increase and a lower PBT can also be obtained with a greater income from biogas and

fertilizer.
10

In an inclusive research, the AD of cattle, swine, and poultry wastes with carefully chosen

ratios is carried out to evaluate their biogas yields. The research affirms that a farm owner can

get optimum biogas by blending cattle dung, swine, and poultry wastes in the precise ratio of

1:0:1 or 4:1:3 and that temperature variations within the mesophilic range do not affect biogas

formation.
11

A study illustrates that the popularity of biogas surges to a peak by upgrading to numerous

available efficient forms of fuel. Taking into account energy efficiency and global warming

potential, the study of conversion of biogas to compressed biogas (CBG), liquefied biogas

(LBG), Fischer-Tropsch Diesel (FTD), methanol, and dimethyl ether (DME) revealed that DME

gave the best performance of the fuel conversion scenarios considered.
12

In another research paper, the effects of storage time and storage temperature on subse-

quent biogas production from cow manure are investigated and its outcomes are that storage of

digestate at 9 �C has no significant effect on consequent biogas production, but at 20 �C, it
decreases from 16.4 m

3
/t to 5 m

3
/t of fresh digestate and a decline of volatile solid concentra-

tion in the stored digestate to 0.4 g/kg/week is also observed.
13

Another remarkable method

named flexible biogas production is employed, which offers the opportunity to minimize the
necessary gas storage capacity and thus saves storage investments predominantly. The authors

conclude that biogas can be produced with high flexibility using diurnal flexible feeding and

precise combinations of substrates with different degradation kinetics.
14

Evaluation of distinctive economic and ecological metrics for multiple objective considera-

tions is undertaken in a life cycle-based accounting model of a domestic biogas system. A typi-

cal household biogas system in Gongcheng, China, is ideal for a case study. The outcomes are

$US 6520 net benefit for each family unit compared to no biogas-linked peasants, savings of

1266.67 m
2

firewood for each household biogas unit, and reductions of 4120 kg of CO2 and

34.7 kg of SO2 emissions, which equate to 1.86�109 J and 1.70�107 J of environmental emis-
sion energy saved. The resulting CO2 reduction would be worth $US 2.34�107 of potential
carbon trading value for the whole of Gongcheng. Indirect social benefits include diminution of

germs dispersal, enhancement of labor intensity, etc.
15

In a noteworthy article,
16

the authors show that biogas production can affect the emissions

of GHGs in a number of ways, but considering other factors relating to farm-scale AD like fer-

tilizer replacement, firewood substitutes, lighting kerosene, increased agricultural production,

green area augmentation, etc., these GHGs are well-balanced.

023101-2 Das et al. J. Renewable Sustainable Energy 8, 023101 (2016)

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Household air pollution is ascribed as the cause of global deaths of 4.3�106 people and
60% of those are owing to cardiovascular complications while 40% are due to adverse effects

on respiratory health.
17

Most conspicuous sufferers are women and children because of the defi-

ciency of ventilation, fuel type, kitchen volume, stove type, eave spaces in kitchen walls, etc.
18

High levels of cardiovascular disease, stroke risk, high blood pressure, etc., are found among

adult females of rural areas where solid wood is used for cooking.
19

An allied research team

conducted an epidemiological study to assess the real-life impact of biogas interventions on the

risk of hypertension in rural Nepal considering two groups of cooks—(i) aged greater than 50

years and (ii) aged between 30–50 years. The study indicated that systolic blood pressure (SBP)

increases with increasing age, diastolic blood pressure (DBP) decreases after 50 years, and

lower SBP and DBP are more marked in biogas users than wood users.
18

Statistics show that,

in India, 90% of total household energy consumption is for cooking, and most of this

uses biomass resources like cow dung, fuel wood, crop residues, etc.
20

Cooking takes up about

6 Hr/day in rural areas for a typical family due to the low calorific value of solid fuels, which

causes slow burning and low efficiency of mud stoves. The study correspondingly relates that

one of the major reasons of school dropouts among rural children is being busy with wood

collection.

In another study, it was observed that AD-induced increases in phytotoxic substances such

as ammonia, volatile organic compounds, or nutrient discrepancies counteracted by agronomic

measures, which in turn recuperates plant growth and overwhelms disease likelihoods.
21

An excellent planning concept has been pioneered for implementation of renewable energy in

local communities in developing countries, exemplified by a Vietnamese case.
22

Comprehensive

researches and pilot projects have been performed in many countries like Germany, Denmark,

Sweden, China, Serbia, Kenya, Croatia, and so on, and demonstrate benefits that cut across issues

of dimension, scale, and resilience.
23–28

Germany has made auspicious progress through amend-

ments in legislation requiring 80% renewable power consumption by 2050 and the direct retailing

of biogas power in the German electricity market.
27

Bangladesh is a land of opportunities, but the energy crisis is one of the largest threats to

its development. 70% of the total 161�106 population of Bangladesh inhabit rural areas; how-
ever, only 59.6% of total inhabitants have access to electricity, and almost 48% of rural areas

are still without electrification.
29

The present peak power demand of Bangladesh is 10 283 MW,

and the highest generation is 6674 MW;
30,31

demand is predicted to increase to 33 708 MW by

2030.
32

66.4% of the existing power plants are natural gas based
33

while prevailing natural gas

resources are decreasing continuously and are assumed to dry up by 2030.
32

Hence, the country

is urgently exploring short, medium, and long term alternatives,
32

including planning to set up

nuclear power plants to meet this increasing demand, but there are many technical complica-

tions and debates in this issue.
34

Limited diesel generator facilities exist but are too expensive

and burning fossil fuels is not a sustainable long term option. Owing to climate change and

global warming, Bangladesh is in a potentially catastrophic hotspot of various natural calami-

ties, including floods, cyclones, storm surges, salinity intrusion, extreme temperature, drought,

etc.
35,36

However, burning of fossil fuels worldwide for power generation will, in time, inten-

sify these types of threats alarmingly. Renewable energy sources are regarded as a promising

solution of these pivotal issues.
37

Although the Solar Home System (SHS) has spread out to

some extent in rural areas of Bangladesh, contrariwise, the high price of solar systems and the

low efficiencies of solar panels mean that the SHS certainly cannot be deemed as an outright

solution for the underprivileged populaces of rural communities.
38,39

Besides, only 6% of the

total population of urban areas gets access to a natural gas cooking facility
40

and most of the

rural areas are without any natural gas supply.
41

Those rural people mainly utilize wood

and kerosene for cooking and lighting requirements which, at the end of the day, triggers oblit-

eration of green territory and precarious environmental impacts.
42

In a biogas based research in Bangladesh, the authors report that Bangladesh has an enor-

mous biogas resource potential with its about 200�106 poultry fowls in over 200 000 poultry
farms. Hardly any biogas plants have been installed in these farms till date, so the possibility of

electricity generation has been estimated to have the potential of producing 1.33 TWh of

023101-3 Das et al. J. Renewable Sustainable Energy 8, 023101 (2016)

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electricity per year from the poultry industry. The investigation also summarizes the impact of

different factors on production of biogas in different biogas plants of Bangladesh ranging from

6.4 m
3

to 4000 m
3

capacity and concludes that 75% more biogas can be achieved from well-

equipped biogas plants with modern controlling stratagems.
43

But the cost factors associated

with providing such control systems deter the rural people from adopting these types of plants.

Because the power systems in poultry farms are anticipated to operate in generally isolated

locations with no alternative supply, they must be safe and reliable under all operating condi-

tions. Hence, the authors in a parallel study
44

examined the power system stability of a stand-

alone poultry based biogas plant of Bangladesh under different operating conditions using

software simulation. A research on off-grid electrification carried out for rural Bangladeshi

areas,
45

but the capacity of those ranged from 10 to 50 kW, which is a major constraint for

these systems as electricity demand cannot be so severely limited for proper rural development.

The proposed Energy Neutral Home (ENH) is a system where the homes are clearly energy

neutral by meeting their energy demand via renewable energy resources devoid of taking elec-

tricity from grid. The ENH may well provide abridged costs for infrastructure, such as line

capacity and peak load generation facilities, plus abbreviated network losses and also promote

long-term energy supply security.
46,47

The energy neutral home system (ENHS) is developed

from Bangladesh perspective and is aimed at two cases: (i) ENHS with only biogas for a single

home, which results in a per kWh electricity generation cost of 2.92 BDT (Bangladeshi Taka)

which would be less for a larger collective of houses in an area,
46

(ii) hybrid ENHS using bio-

gas and solar panels collectively as input renewable energy sources, which is found to be more

cost effective in urban areas, yielding a per kWh electricity generation cost of 6.74 BDT. The

study also indicated that this per unit cost is lower than the ENHS design based on a solar sys-

tem alone, but is still not cost effective for rural areas.
47

In another research, it is revealed that

an ENHS is significantly beneficial for load shedding backup in urban areas using human waste

and found to be more advantageous than the widely used Instant Power Supply.
48

But this sys-

tem is not pertinent in rural areas as those are completely without electricity, which does not

validate the question of load-shedding. Additionally, there are no high-rise buildings in rural

areas; hence, human waste collection is not feasible as indicated in the research.
48

In this paper, an effectual biogas based ENHS system is developed to light rural areas,

provide ample cooking gas and bio fertilizer, thereby supporting sustainable rural development

by using readily available cow and poultry manure as the primary sources of energy. This system

also contributes to GHG balancing and promotes a healthy and clean living environment. This

research is designed for a community of 200 houses such that they obtain the basic needs of

modern life; it is an extension of earlier work on the ENHS accomplished for a standard home.

From the experimental and mathematical analysis, it is clearly evident that the proposed

ENHS not only reduces the cost of energy generation, but also assists in the reduction of the

energy crisis and global warming. Per unit electricity production price of this proposed system

is 1.90 BDT ($US 0.0247 [1 BDT¼$US 0.013 is considered]) and the distribution price is
considered at 5.00 BDT ($US 0.065), which is lower than the present tariff rate. As rural

people are dependent on agriculture and fishing for living, slurry of this system can be used as

high quality biofertilizer in fields and as fish food in fishing farms. Though this system is

designed for Bangladeshi rural areas, it can be implemented anywhere around the world where

needed. The research will thus generate new knowledge on how an ENHS can be a viable and

efficient solution to facilitate the provision of electricity to rural communities around the world,

not only ameliorating the energy and environmental crises, but also adding value in areas of the

economy and sustainable development.

II. MATERIALS AND METHOD

The proposed ENHS is designed for a rural community of Bangladesh, which includes a

farming business where 200 nearby houses are considered as the consumers. This system basi-

cally comprises a biogas plant having an inlet chamber, a digester, and an outlet or hydraulic

chamber as presented in the block diagram of the ENHS shown in Figure 1. The gas production

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rates of chicken and cow manures are 0.07 m
3
/kg and 0.037 m

3
/kg, respectively, which are

comparatively higher than other waste sources.
49,50

Hence, this system considers chicken and

cow manures as the primary waste sources from a farm having 96 thousand layers (these are

the chickens which lay eggs and their waste contain high total solid (TS) value) for biogas gen-

eration and 350 cows for optimum performance. Manures are fed to the inlet of the plant,

mixed with water at an appropriate ratio and sent to the digester. The biogas produced by

means of the AD process is collected through a specially designed purifier and processed into

both a biogas generator and a cooking gas line. Electricity is distributed to the 200 houses

through transmission lines associated with control and protective circuitry. For cooking

purposes, specially designed burners are used whose gas nozzles are bigger than usual as biogas

pressure is lower than with natural gas. After digestion, the waste eructates from the digester to

an outlet or hydraulic chamber in wet slurry form owing to high gas pressure in the top of

the digester. This can be used for fish feeding directly and the dry slurry can be used as

bio-fertilizer in agriculture after necessary processing.

A. System demand and management plan

To determine energy demand and other managerial specifics, a standard home of a rural

Bangladeshi region is considered as the analytical base of the proposed research. The gas con-

taining capacity of that standard energy neutral home is 6 m
3
, which is used for both cooking

and electricity generation purposes in the proportion of 33% and 67%, respectively.
46

The total

energy demand of that system is 669 W,
46

which is also considered as the benchmark for the

proposed ENHS with the inclusion of computer provision and slight tweaking in load configura-

tion as demonstrated in Table I. The expected load curve for electricity supply of a standard

home is displayed in Figure 2.

The total estimated daily electricity demand for the proposed ENHS of a rural community

of 200 houses is 577.3 kWh and the corresponding load curve is depicted in Figure 3. This

assumption is made according to the load condition of a standard home combined with consid-

ering some other factors, viz., financial condition, family size (number of family members),

size of houses, etc. Although the system includes a standard home rating, given the factors

FIG. 1. Block diagram of the proposed ENHS.

023101-5 Das et al. J. Renewable Sustainable Energy 8, 023101 (2016)

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stated above, not all homes use a refrigerator, computer, etc., which may establish a variation

in the load assumptions of Figure 3. The load curve discloses that maximum electricity demand

is 59.4 kW in the peak hours from 6 pm to 10 pm. By and large, 1.4 kWh electricity generation

entails 1 m
3

biogas and a biogas burner requires 0.4 m
3

of biogas for a 1 Hr cooking period.
50

The ENHS scope considers two biogas burners for 2.5 Hr of cooking for a family per day,

which amounts to 2 m
3

biogas. Hence, for the total community, the required biogas for electric-

ity generation is 426.64 m
3

and cooking gas is 400 m
3

per day. Therefore, the percentages of

biogas usage for electricity generation and cooking of the designed ENHS are 52% and 48%,

respectively, as shown in Figure 4.

B. System design

The main part of the entire system is the biogas plant and its two core components are the

digester chamber and hydraulic chamber. Schematic design details of the biogas plant are

exhibited in Figures 5 and 6. The various design parameters are listed in Table II. Manure from

cow/poultry farms is fed to the inlet via a waste storage chamber and mixed with water at ratios

of 1:1 and 1:2 for cow and poultry wastes, respectively.
50

A water supply system is assimilated

with the inlet to supply essential water during the mixing process. A specially designed mixer,

coupled with a motor, is set in the interior of the inlet chamber and is used to blend the diges-

tate to yield the anticipated total influent by dint of an appropriate control system. The total

load of this mixing system is assessed as 10 kW in light of four 1-A induction motors each of
3 hp, 1600 rpm, plus a water pump of 1.5 hp and 2 Hr mixing time per day. The coupling of

motor to impeller shaft is via a gear box of ratio near to 4:1 for operating the mixer at around

400 rpm to ease the mixing process; else the apt mixing is not achievable, i.e., the mixing time

increases with lower rpm and, for higher rpm, the mixing mechanism may collapse. The total

TABLE I. Energy demand of a standard home for the proposed system.

Load Rating (W) Number Total Power (W)

Energy saving bulb 15 2 30

Energy saving bulb 25 2 50

Energy saving bulb 12 2 24

Ceiling fan 75 3 225

Color TV 100 1 100

Refrigerator 150 1 150

Computer 80–90 1 90

Total 669

FIG. 2. Load curve for electricity supply of a standard home.

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FIG. 4. Proportion of biogas for electricity generation and cooking.

FIG. 3. Load curve of the ENHS for a community.

FIG. 5. Schematic diagram of biogas plant.

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mixed influent is channeled throughout a manual shutter to the stone settle pit, from where the

detrimental contents of poultry or cow manure such as small stones, snails, etc., can be readily

removed before the entry of digestate to the digester dome, thus extending the life time of the

digester. The generated biogas is drawn from the gas collecting chamber of volume Vc, as indi-
cated in Figure 5. The wet slurry from the hydraulic chamber exits automatically to the slurry

pit whose construction should be such that facile collection of dry slurry is possible (usually

the length should be double the height). For an optimum design of the plant, some factors are

FIG. 6. Measurement parameters of digester.

TABLE II. Design parameters of the biogas plant.

List of design parameters

Vi¼Volume of inlet f1 5 Extent of upper parabolic chamber of digester
Vc¼Volume of gas collecting chamber f2 5 Extent of lower parabolic chamber of digester
Vgs¼Volume of gas storage chamber Hi¼Clearance between lower level of both inlet

and stone settle pitVf¼Volume of fermentation chamber
Vs¼Volume of sludge layer H1¼Clearance of inlet pipe from flexible cover of

stone settle pitVH¼Volume of hydraulic chamber
Vsp¼Volume of stone settle pit H2¼Level of stone settle pit from insertion point of

inlet pipe to digesterVws¼Volume of waste storage chamber
Vw¼Volume of water tank H¼Height between lower level of gas storage

chamber and sludge layerV1¼Volume of upper parabolic chamber of digester
V2¼Volume of middle cylindrical portion of digester h1¼Height of the hydraulic chamber from digester

manure level;V3¼Volume of lower parabolic chamber of digester
V¼Total volume of the digester¼VcþVgsþVfþVs h¼Height of the hydraulic chamber to lower level

of gas storage chamberDi¼Diameter of inlet
D¼Diameter of digester HH¼Height of the hydraulic chamber
DH¼Diameter of hydraulic chamber Hss¼Height of the slurry pit
R1¼Radius of upper parabolic chamber of digester Wss¼Width of the slurry pit
R2¼Radius of lower parabolic chamber of digester Lss¼Length of slurry pit

h¼Inclined angle of inlet pipe

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presupposed, viz., Vws > Vi, Vw�Vws for cow waste and Vw�2Vws for poultry waste according
to the mixing ratio, Vsp�Vi /4, Lss�2Hss, etc. Design parameters of the biogas plant are com-
puted considering these prerequisites along with Infrastructure Development Company Limited

(IDCOL) standards,
50

but the parameters may diverge depending on the plant location.

Geometrical assumptions for digester design calculations are displayed in Table XII in

Appendix A. For continuous system operation, three different digesters, each containing 32 000

layers and another fourth digester with 350 cows are deemed necessary. Hydraulic Retention

Time (HRT) at 30 �C temperature is considered as 40 days.50 10 kg and 100 g manure are
obtained per day from each cow and layer, respectively.

51,52
TS percentages of fresh discharge

are 16% and 20%, respectively, and total influent is calculated considering 8% favorable condi-

tion of TS value.
53

According to these standard data and using Table XII in Appendix A and

Eq. (B1), design calculations of digester and hydraulic chamber for both 350 cows and 32 000

layers are presented in Table III. The assumed value of inclined angle of inlet pipe, h, is the
same for all digesters of the system and its value is 60�.50 The rest of the design parameters
revealed in Figures 5 and 6 are appraised based on assumptions which may vary on account of

the geographical location of the plant. Thus, the system is optimized based on available litera-

tures, practical implementation,
46

associated technologies and necessary assumptions.

According to the above calculations, an overview of the plant, including inlet, outlet, and

digesters, with generators in combination, are detailed in Figure 7 where all evaluated design

parameters, generator capacities and running times, and generators’ connections with the spe-

cific number of digesters are portrayed. Figure 8 exhibits the overall supply connection of

digesters-generators-users and digesters-common biogas line-users. The generated electricity

and biogas of the ENHS are delivered to the users from the generator block through a common

grid line and common biogas line, respectively.

Biogas comprises some undesirable impurities, viz., H2S, moisture, vapor, etc., which must

be removed before consuming the gas. Amongst these, H2S is the most problematic, since it is

toxic as well as corrosive. Although the proportion of H2S in biogas composition is very low

(0–1%),
54

even its slight presence can cause some damage to the generator and hence lowers

the system life time while environmental aspect is beyond the discussion.
55,56

Hence, a special-

ized purification unit is employed in the system, as shown in Figure 9, which contains 3 cham-

bers.
50,52

Chamber 1 is known as the water trap and it sucks the water content from the biogas.

Chamber 1 acts as a simple filter, which has a pipe inside with a certain height and span where

the biogas strikes to the inside wall. Hence, the water content of biogas is detached and stored

TABLE III. Volume calculation data of digester and hydraulic chamber.

Parameters

Value

350 cows 32 000 layers (Hydraulic chamber)

Total influent (Q) 7000 kg 8000 kg Parameters Value

Water to be added 3500 kg 7360 kg 350 cows 32 000 layers

Working volume 280 m
3

320 m
3 Vs 52.5 m

3
60 m

3

(Digester) Vgs 196 m
3

224 m
3

Vdis 7 m
3

8 m
3

V 350 m3 400 m3 Gas chamber volume 89.32 m3 101.85 m3

D 9.22 m 9.63 m Pi 4 kPa 4 kPa

H 3.69 m 3.85 m Pf 9.8 kPa 12.79 kPa

f1 1.844 m 1.926 m h1 0.7 m 1 m

f2 1.1525 m 1.2 m h 0.3 m 0.3 m

R1 6.6845 m 6.98 m HH 1 m 1 m

R2 9.8 m 10.23 m DH 2.98 m 3.19 m

V1 64.82 m
3

73.85 m
3

Vc 17.5 m
3

20 m
3

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at the bottom of the chamber. The stored water is removed using a tap under chamber 1 after

six months.
52

Chamber 2 holds iron (Fe) chips and it is the most significant portion, as this

chamber eliminates the noxious H2S according to following reaction:

Fe þ H2S ¼ FeS þ H2
.

FIG. 7. Overview of the ENHS for a community of 200 homes.

FIG. 8. ENHS for rural community.

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Chamber 3 has silica gel within it and removes vapor or moisture from the biogas.
57

Iron

chips are inspected at least twice a year and regenerated or replaced if required, depending on

its condition, whether it is fully oxidized or not. On the other hand, the silica gel is inspected

quarterly every year and replaced when its original color changes, which depends on biogas

flow rate through the purifier.
52

The design parameters of the biogas purifier are denoted in Figure 9, where lp1 and lp2 are
spans of the respective chambers, lp3 is height of inlet pipe placement, lp4 is span of inlet pipe
into chamber 1, dp1 and dp2 are the diameters of the cylindrical chambers. These are assumed
such that lp3� lp1/3, lp4 is slightly less than overall diameter dp1, dp2 > dp1, and lp2 > 1.5lp1,
which vary with digester size and generator capacity.

52

Table IV indicates gas production capacity (Vgs) of each of the three chicken manure
digesters is 224 m

3
and the fourth one for cow manure is 196 m

3
, which sums the total gas pro-

duction capacity of the system as 868 m
3

and indicates generator capacities for the best per-

formance. Gas generators for generating electricity from biogas are reliant on load demands

around different times as displayed in Figure 10. Figure 11 explores generator operating sched-

ule at different times to meet the pivotal load demand of this system in an assured way. The

graph in Figure 12 presents electricity generation by the system for 24 Hr according to the

schedule periods of Figure 11. As generator 6 is dedicated for running inlet systems and other

auxiliaries, it is not included in further load analysis.

The test case prototype of this developed ENHS is implemented (as shown in Figure 13)

for a standard home at Mr. Anil Kanti Das’s residence, located in Rangunia, Chittagong,

Bangladesh. Figure 13 provides some photographs of the implemented prototype.
46

An area

within a 1 km radius is assumed, including 200 families, as a test case area for this system. The

FIG. 9. Schematic diagram of biogas purifier used in the ENH system.

TABLE IV. Digester vs. generator capacity.

Digester No. Designed for Gas production capacity(m
3
/day) Generator No. Generator capacity (kW)

1 32 000 layers 224 Gen-1 10

2 32 000 layers 224 Gen-2 5

Gen-3 20

3 32 000 layers 224 Gen-4 40

4 350 cows 196 Gen-5 10

(Sum¼868 m3) Gen-6 10

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FIG. 10. Effective working time of generators.

FIG. 11. Generator scheduling.

FIG. 12. Electricity generation over a day.

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analysis and related design calculations are made based on the practical data from this proto-

type, GTZ (Deutsche Gesellschaft fur TechnischeZusammenarbeit) and IDCOL Bangladesh.
51,52

III. RESULT AND ANALYSIS

Net present value (NPV) and payback period analysis are used to determine economic via-

bility of the model. The equation for NPV is presented in the following equation:
58,59

NPV ¼
Xn

t¼0

CFt

1 þ kð Þt
: (1)

Here, CFt¼cash flow of the investment in time period t; k is the discount rate; and t is the
time period from 0 to n years.

Again, payback period (PBP) is calculated as
60

PBP ¼ Cinit = Cin; (2)

where Cinit¼ initial investment and Cin¼annual cash inflow.
All costs are estimated based on vendor’s retail price.

50,52
Taking the total life time of this

ENHS for a rural community to be 20 years
61

and given the cost of a 500 CFT (Cubic Foot)

[1 m
3¼3.283 CFT] digester is about 70 000 BDT ($US 910),62 brief digester costs in addition to

hydraulic chamber and inlet recharge chamber costs are set out according to Figure 7, which

results in a total cost of 7 963 710 BDT ($US 103 528) to construct the stated four digesters. The

purification system cost is dependent on digester size plus generator capacity and is determined

according to market prices of 80 000 BDT ($US 1040) for each digester for 32 000 layers and

60 000 BDT ($US 780) for the digester for 350 cows. The model requires 4 stone settle pits of

10 000 BDT ($US 130) each and 4 waste storage chambers of 40 000 BDT ($US 520) each.
52

Cost for mixing system ¼ 4 �ð3 hp Induction motor þ Gear boxðfor motor controllingÞþ ImpellerÞ
¼ 4 �ð14 500 þ 4 200 þ 10 000ÞBDT ¼ 114 800 BDTð$US 1492Þ:

Cost for water supply system ¼ 1:5 hp water pumpþ3�8000 L water tanks½for digesters 1; 2 and 3�
þ4000 L water tank½for digester 4�
¼ 16 000þ3�ð8000�9Þþ4000�9 BDT
¼ 268 000 BDTð$US 3 484Þ:

FIG. 13. Implemented energy neutral home system.

023101-13 Das et al. J. Renewable Sustainable Energy 8, 023101 (2016)

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Complete purification cost for this model is estimated as 300 000 BDT ($US 3900) and pipeline

and other costs as 600 000 ($US 7800). Total plant cost (TPC) is thus determined as 13 499 884

BDT ($US 175 498), and the detailed cost calculations are tabulated in Table V.

For long term operation, additional costs comprising top overhaul cost and major overhaul

cost along with the ongoing repair cost should be reckoned. Top overhauling is entailed after

10 000 Hr of generator operation that costs 15% of Gcost and the major overhauling has to be
done after a further 10 000 Hr of operation at a pricing of 50% of Gcost.

62
Total operating cost

for the system taking into account overhaul and repair costs of the generators is 2 315 500 BDT

($US 30 101) as analyzed in Table VI.

From Figure 4, electricity used in a day is calculated as 577.3 kWh to meet load demand.

Additional 20 kWh electricity is also required to keep the inlet, mixer, and water supply system

running. The total required electricity generation per day is 597.3 kWh, which requires 426.64 m
3

biogas.
50

400 m
3

biogas is necessary for cooking purpose of 200 families considering 2 m
3
/day

gas demand to each family.

In accordance with the percentage split of biogas consumption, as shown in Figure 4, cook-

ing gas generation cost encompasses 52% of total biogas generation and supply related costs

while the cost of electricity generation is estimated considering 48% of total biogas generation

costs together with generator, transmission line, and other circuitry costs.

Cooking gas generation cost ¼ 52% of digester cost þ 52% of inlet system cost
þ 52% of purification cost þ pipelining cost
¼ 5 200 186 BDT � $US 67 602

Per unit cooking gas generation cost ¼ cooking gas generation cost = total gas generation in 20 years
¼ 1:78 BDT � $US 0:023ðper m3Þ

Electricity generation cost¼48% of digester costsþ48% of inlet system costþ48% of
purifier costþgenerator costþ total operating cost of generatorsþ transmission line and other
circuitry costs¼8 299 698 BDT�$US 107 896.

Per unit electricity generation cost¼electricity generation cost / total electricity generation
in 20 years¼1.90 BDT�$US 0.0247 (per kWh).

Monthly cooking gas bill is assumed 800 BDT (�$US 10.4) for each family. The daily
electricity consumption varies from home-to-home due to the socio-economic conditions of rus-

tic people. The monthly income of the ENHS for electricity consumption with a rate of 5.00

TABLE V. Total plant cost of the designed model.

SL Capital cost item BDT

1 Digester construction 7 657 390

2 Hydraulic chamber and inlet construction 306 320

3 Stone settle pit 40 000

4 Waste storage chamber 160 000

5 Mixing system 114 800

6 Water supply system 268 000

7 Purification unit 300 000

8 Pipeline and others 600 000

9 Generator cost 1 530 000

Subtotal plant cost (SPC) [1þ2þ7þ8þ9] 10 393 710 ($US 135 118)
10 Transmission line and protective circuitry (2% of SPC) 207 874

11 Total operating cost of generators 2 315 500

Total plant cost (TPC) 13 499 884 ($US 175 498)

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BDT (�$US 0.065) per kWh is detailed in Table VII, and the yearly revenue of the system is
enumerated in Table VIII.

As the system incorporates the employees of the farming business into the ENHS also, it

does not require more workers for system management. However, the system employs two

laborers at 10 000 BDT (�$US 130) each per month and an accountant at 15 000 BDT (�$US
195) per month on a fulltime basis. The total operating cost (TOC) of the model is summarized

in Table IX, and all investments, expenses, and earnings are briefed in Table X. Finally, the fi-

nancial evaluation of the proposed model is calculated and presented in Table XI, which results

in the system being economically viable.

IV. DISCUSSION

This study developed an ENHS for rural communities which will not only play an active

role in reducing the energy crisis and costs of energy generation worldwide, but also reduces

greenhouse gas emissions into the atmosphere. From the study, it can be clearly demonstrated

that the proposed system will be beneficial to society in a number of ways, which are presented

in Subsections IV A–IV H.

A. Case-1: Retail price of electricity

According to the retail tariff plan of the Rural Electrification Board (REB) for the fiscal

year 2013–2014, the per kWh electricity price for domestic users is 3.36–3.87 BDT,
63

and

including line charge and all other service charges, it becomes 5.92 BDT, which is proposed to

increase from 7% to 18.86% depending on the load level.
64

But load shedding is a very com-

mon hazard in rural areas and no new electricity connections are allowed. In this ENHS, elec-

tricity price is estimated as 5.00 BDT per kWh, which is lower than the REB tariff with the

ENHS providing assurance of supply continuity and reliability. The costs of electricity from

TABLE VI. Generator Overhaul and Repair Costs.

Gen.

No.

Operating

time (Hr)

Top overhaul Major overhaul

Total

overhaul

cost

(BDT)

Total

generator

overhaul

cost (BDT)

Repair

cost

(BDT)

Total Operating

Cost of

generators

(BDT)

Required

times

Total cost

(15% of Gcost
each time)

(BDT)

Required

times

Total cost

(50% of Gcost
each time)

(BDT)

Gen-1 102 200 5 127 500 5 425 000 552 500 2 115 500 200 000 2 315 500

($US 30 101)Gen-2 73 000 4 42 000 3 105 000 147 000

Gen-3 58 400 3 135 000 2 300 000 435 000

Gen-4 43 800 2 195 000 2 650 000 845 000

Gen-5 29 200 1 25 500 1 85 000 110 500

Gen-6 14 600 1 25 500 … … 25 500

TABLE VII. Monthly electric bill calculation.

House No.

Electricity consumption/day

(kWh)

Per unit

rate (BDT)

Monthly

bill (BDT)

Total monthly electric

bill (BDT)

1–10 114.6 5 17 190 86 610 ($US 1126)

11–40 147 5 22 050

41–60 63.6 5 9540

61–80 50 5 7500

81–100 16.2 5 2430

101–150 141 5 21 150

151–200 45 5 6750

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other renewable sources are much higher, viz., electricity from solar system costs 13.7 BDT

(�$US 0.178) per kWh.65

B. Case-2: Per unit electricity generation cost

It has been seen from the results that the electricity generation cost for this system is 1.90

BDT covering transmission and distribution costs. However, the per unit cost of electricity gen-

eration for recently available quick rental power plants (QRPPs) and Independent Power

Producers (IPPs) is 4.75 to 5.39 BDT and 1.40 to 3.80 BDT, respectively, from natural gas

while it is 15.21 to 15.30 BDT and 16.27 to 16.70 BDT, respectively, from furnace oil.
66

Government is subsidizing this sector to provide electricity at reasonable prices, which costs a

huge amount of the budget every economic year. The country subsidizes in two categories,

power generation and distribution. The first step reduces the generation cost to an average of

5.36 BDT per kWh, and the second step minimizes the distribution tariff to consumers, which

was a cost to the national budget of 65.6�109 $US in 2013.67

TABLE X. Summary of investment, expenses, and earning.

Investment (TPC) 13 499 884

Yearly income 2 959 320

Yearly expenses (TOC) 505 000

Yearly earning 2 454 320 ($US 31 906)

TABLE XI. Financial evaluation of the proposed System.

Discount rate % 12

Payback period (PBP) Years 5.5

NPV, 20 years BDT 18 332 405

Net Profit BDT 50 313 560 ($US 654 076)

TABLE VIII. Yearly revenues from the model.

Revenues BDT/month BDT/year

Cooking gas charge 160 000 1 920 000

Electric bill 86 610 1 039 320

Total revenues 2 959 320 ($US 38 471)

TABLE IX. Summary of total operating cost (TOC) of the System.

Item Cost item BDT/year

Fixed operational cost (FOC)

1 Personnel cost 420 000

2 Overheads

Variable operational cost (VOC)

35 000

3 Repair and maintenance 50 000

Total operating cost (TOC) 505 000 ($US 6565)

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C. Case-3: Lighting (ENHS vs. kerosene)

People usually use kerosene for lighting purposes in rural areas, which costs almost

500–600 BDT per month for a standard family
68

and also causes environmental as well as

health hazards due to kerosene burning at home.
69

In this system, electricity supply from the

renewable source abolishes this kerosene cost and safeguards the healthy environment at home.

Lighting of houses, schools, etc., of remote areas with the ENHS gives rural kids and students

better conditions for study and hence they can utilize their time effectively, which finally leads

to social development of rural areas.

D. Case-4: Cooking benefits

The present tariff rates of single and two burner stoves are 400 BDT and 450 BDT, respec-

tively.
70

But recently a price increment proposal of 1000 BDT for two burners and 850 BDT

for one burner was submitted to the Bangladesh energy regulatory commission, being 122.22%

and 112.50% increments, respectively.
71

A survey in a village Pomra, Rangunia, Chittagong,

Bangladesh, reveals that the cooking wood cost for a typical family is around 2000 BDT/

Month while Liquified Petroleum Gas (LPG) costs around 3000 BDT/Month. Again, some peo-

ple use kerosene stoves for cooking, which costs almost 2500 BDT per month. In this system,

the cooking gas price is fixed at 800 BDT, which is cheaper than the current cooking cost in a

rural area considering the factors as stated above. Therefore, this ENHS provides a significant

saving from cooking gas usage. As can be predicted from the statistics,
40,41

there is no chance

of a natural gas supply facility being available in rural areas in the foreseeable future; hence,

this ENHS brings this facility to rural people along with good financial savings, which finally

leads to the socio-economic development of rural communities of Bangladesh. This cooking

gas facility additionally ensures a healthy cooking environment and saves cooking wood collec-

tion time,
20

which leads to rural life development. In such instances, the mothers will get more

hygienic cooking conditions which will reduce the probability of food poisoning and sickness,

particularly among poor children. Therefore, ENHS will be a wonderful solution in rural areas

of Bangladesh where the potential of biomass and biogas energy sources is enormous.

E. Case-5: Environmental impact

Natural gas required for 1 kWh electricity generation is 1000 CFT.
72

Consequently, this

system generates a total of 577.3 kWh electricity for consumer supply with biogas which saves

577 300 CFT of natural gas resources per day. Furthermore, per kWh electricity production

from natural gas emits a maximum 891 g CO2
73

to the environment which would cause about

514.4 kg CO2 emission per day to serve this rural community system demand using natural gas,

while a maximum 333.6 kg CO2 is emitted by electricity generation from biogas in this pro-

posed ENHS.
54,74

In rural areas, usage of non-purified biogas containing H2S is evident from

the fact that tin shaded rooftops of kitchens are damaged very quickly with burning and hence

introduces extra cost, hazards, etc.
75

Again, it stimulates oxides of sulfur while burning which

ultimately prompts severe acid rain and serious greenhouse effects.
76

It also reduces generator

lifetime significantly, and GI pipeline is damaged very early if the supplied biogas contains

even a small portion of H2S. However, in this system, biogas is purified with the removal of

H2S as it is a very perilous component of biogas for generator and cooking. Consequently, this

system will reduce the emission of GHGs from the generation sector as well as the residential

sector, which will diminish global warming and climate changing impacts.

F. Case-6: Ease of waste management

As the business of poultry and cow farming is spread through rural areas along with the

system, it makes the waste management of the farm easy and profitable. In large scale poultry

and cow farms, massive amount of wastes are created every day, which are incredibly difficult

to dispose of in an environment-friendly way. In rural areas of Bangladesh, these fresh wastes

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are openly used as biofertilizer on crops, which is not useful focusing various factors as dis-

cussed in this research.
21

However, such fresh wastes require a lengthy period to turn into a

fertilizer and, in the course of this open digestion process, the high methane content of those

fresh wastes causes 21 times greater greenhouse effects than of a CO2 molecule.
77

From that

point of view, this system introduces an environment-friendly way of appropriate waste man-

agement. An attractive benefit of this system for rural people is that the raw slurry discharged

from the digester outlet can be used as fish nutrition in pond or fish farm adjacent to the plant,

and also as quality biofertilizer
21,78–84

in agriculture.

G. Case-7: Social impact

In this research, provision for using computers in a rural community where electricity has

not yet reached may not seem appropriate, but bearing in mind the country’s goal of exploiting

modern technological advancements and telecommunications, it is readily foreseeable that, if

proper amenity is bestowed to these diligent and talented rural people, this will create a signifi-

cant difference and there will be a technological revolution countrywide. As electricity is a key

factor to improve medical services in remote areas, implementation of a system like this

permits vaccination, sterilization, and surgery, and hence, an improvement over time in the

quality of the medical services will be possible. These better working conditions may attract

more qualified doctors and nurses to work in rural environments. Moreover, this system creates

job opportunities for rural people as plant operators, accountants, etc., generates opportunities

for both small and large businesses outside the heavily populated cities of the country by dint

of improved accessible amenities and, as a consequence, the ENHS helps to diminish poverty.

H. Case-8: Reduction of deforestation

The cooking wood requirement for a standard family per year is 4.24 tons.
85

Thus, this

system saves the community 884 tons per year of wood from household cooking, which in turn

saves a large amount of trees from being cut down. Again, these saved green trees will reduce

GHG effects on the environment in a substantial way and assist with greenhouse gas balance.
16

V. FUTURE RESEARCH SCOPES

The comprehensive model will yield a sensible and simplified platform that provides the

detailed information for possible deployment of an ENHS for rural communities not only in

Bangladesh but also in other countries around the world. This study is still in its preliminary

phase and so there is an ample scope for ancillary research on this system in the following

areas:

• Development of simulation model to validate the experimental and mathematical analysis.
• Development of ENHS based chain business model for a rural community.
• Development of ENHS in larger scale.
• ENHS with more enhanced purification capacity.
• Updating of the system considering other socio-environmental factors.
• ENHS design for urban areas where a vast quantity of municipal and human waste is available.

VI. CONCLUSION

Energy crisis in the rural areas, costs of energy generation, and environmental awareness

have encouraged interest to generate more energy from renewable energy sources either through

off-grid or grid connected systems. Therefore, in line with the current initiatives, this study

developed the methodology for a reliable and efficient ENHS that can provide reliable and

uninterrupted power supply to a rural community. This research presents a new and applicable

solution to assist rural communities by providing affordable renewable energy, cooking gas,

high quality fertilizer, job opportunities, and environmental safety, and hence enhance the over-

all scope for the sustainable development of rural life. This designed system can produce

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577.3 kWh electricity per day, sufficient for 200 houses, which is greatly profitable for plant

owners. This system not only provides energy at least cost but also ensures environmental

safety as well as high quality fertilizer for agriculture and fishing. This system provides gas to

rural people for cooking which in fact saves green territory. Therefore, to overcome energy cri-

sis and improvise large rural communities of Bangladesh as well as other countries alike, this

community based energy neutral home system can be a reliable and effective solution.

APPENDIX A: GEOMETRIC ASSUMPTIONS OF DIGESTER CALCULATIONS

See Table XII.

APPENDIX B: BOYLE’S LAW

• The normal pressure of the digester¼Pi.
• The final pressure of the digester¼Pf.
• According to Boyle’s law, for pressure calculation of hydraulic chamber,

Pi �ðtotal gas produced þ 4:09Þ¼ Pf � 4:09: (B1)

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TABLE XII. Geometrical assumptions for digester design.
51

For volume For geometrical dimensions

Vc � 5%V D ¼ 1:3078 � V1=3

Vs � 15%V V1 ¼ 0:0827D3

Vgs þ Vf ¼ 80%V V2 ¼ 0:05011D3

Vgs ¼ VH V3 ¼ 0:3142D3

Vgs ¼ 0:5ðVgs þ Vf þ VsÞK, where K¼gas production
rate per cubic meter volume per day.

For Bangladesh K¼0.4 m3=day

R1 ¼ 0:725D

R2 ¼ 1:0625D
f1 ¼ D=5
f2 ¼ D=8

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