Abstract:
Nowadays, green hydrogen production through electrolysis of water, using
renewable energy sources like solar, wind is increasing worldwide, as it leaves no
emission behind. This work is intended to identify the diversified applications of
hydrogen in different sectors in Bangladesh like the chemical, food and metal
industries, fuel cells, bio-gas, heating applications, etc.
In this research, a green hydrogen production system has been developed
using locally available materials and technologies. An electrolyzer is the central part
of this system. It has two cells connected in parallel and has bipolar electrode
configuration. Each cell has 4 individual electrodes and one shared electrode. Total
9 electrodes have been used. Each electrode is positioned having an equal separation
from each other so that each electrode gets equal potential difference across them.
Here, 10.6 volt is applied to the assembly, and hence, each pair gets 2.65 volt. NaOH
solutions of different molarity are used to optimize the gas production rate.
Performance analysis of developed system shows that it can produce 92.5% pure
hydrogen with 30.62% efficiency and the production rate is 206 mL/min or 1.104
g/h or 0.0123 Nm
3
/h. A practical study on different electrolysis conditions are tested
before developing the electrolyzer. The study concludes that the solar photovoltaic
panels and wind turbines are technically feasible for water electrolysis.
Wind speed data was collected for one year (July, 2015 to June, 2016 and
July, 2016 to June, 2017) at two sites in Chattogram and Dhaka, two busy
metropolitan cities in Bangladesh. The Weibull distribution of data shows that the
shape factor of the wind data in Dhaka (Lat: 23.7390° N, Long: 90.3831° E) is 1.42
and scale factor is 1.96 ms
-1
at measured height of 27 meters from sea level. The
shape factor for Chattogram (Lat: 22.2877° N, Long: 91.7751° E) site is 1.8 and the
scale factor is 2.2 ms
-1
at the height of 59 meters from sea level. It is found that the
scale factor significantly improves with the increase of hub heights. For Chattogram
site, scale factor is around 3.68 ms
-1
at a height of 130 meter, and for the Dhaka site
it is nearly 4.17 ms
-1
at 200 meters.
At measured height the yearly average energy density would be 7800 Whm
for Dhaka site and for Chattogram site it would be around 12300 Whm
. The site
specific wind characteristics suggest that the turbines having 2 ms
-1
cut-in-speed and
10 ms
-1
rated speed would produce energy with 30% capacity factor, from the month
of April to September, for both the sites. For the urban building rooftops, lightweight
small capacity (~1kW) wind turbines with mentioned characteristics are most
suitable. DB 400 and AWM-1500 model turbines have the similar characteristics and
were chosen for the further simulation.
The values of the global solar radiation (taken from NASA for July 1983 to
June 2005) are 4.59 kWh/m
2
/day and 4.76 kWh/m
2
/day for Dhaka, and Chattogram,
respectively. The average sunshine hour for both the cities are about 4.5 hours/day.
The economic feasibility, especially the Levelized Cost of hydrogen,
produced from PV and wind based power options, have been determined. Life-cyclecost
analysis
shows
that,
the
production
cost
of
hydrogen
of
a
plant
using
Solar
PV
power
is
about
BDT
859.77/Nm
3
or BDT 9.56/g. The electricity consumption of the
developed hydrogen plant is 3897.6 kWh/year and the energy requirement for
hydrogen production is about 108.72 kWh/kg. The amount of hydrogen yield is
35.85 kg or 398.56 Nm
3
per year. Sensitivity analysis based on different parameters
finds that the production cost of hydrogen using solar power varies from BDT 7.99/g
to BDT 10.93/g or BDT 718.85/Nm
3
to BDT 982.99/Nm
3
. The cost includes lead
acid battery cost, replacement cost and maintenance costs. On the other hand, for
wind power scheme, the production cost is about BDT 10.30/g or BDT 926.66/Nm
.
For wind-solar hybrid model, the production cost of hydrogen would be BDT 7.47/g
or BDT 671.71/Nm
3
with reduced number of battery usage. Sensitivity could impact
the cost to vary between BDT 7.28/g or BDT 654.50/Nm
3
to BDT 10.11/g or BDT
909.64/Nm
3
. Based on the simulated results, it is found that the solar-wind hybrid
model would be the most effective for green hydrogen production in Bangladesh.
Demand potential of hydrogen is estimated to cope with the targets of
Bangladesh Government by 2040. The demand potential analysis is based on the
methods and criteria adopted by the several international agencies, research institutes
and laboratories. Out of several methods and assumptions, three scenarios, each
having a specific percentage of different fuel mix are selected, modified and set for
Bangladesh. For Scenario-1, the least GDP growth case, Bangladesh would require
about 2.98 MTOE of hydrogen in 2040. The Scenario-2, set for the moderate GDP
growth case would require about 6.05 MTOE and for Scenario-3 which is the
maximum expected GDP growth case, the hydrogen requirement would be 9.12
MTOE. The power sector would consume about 70% whereas industries and
transport would consume 23% and 6%, respectively. However, considering the
socio-economic conditions of Bangladesh, Scenario-1 could be achieved easily with
the projected time period to enter in the world hydrogen economy.
In comparison to the current international cost of hydrogen, the developed
electrolyzer shows higher production cost. The developed unit is a small capacity
electrolyzer and works properly to produce green hydrogen. Research should be
conducted to develop large scale electrolyzer in Bangladesh to evaluate the cost from
large scale production unit. Technology transfer may also help to establish green
hydrogen economy. Due to the availability of solar and wind resources, solar PV and
wind turbine technology would largely contribute to the green hydrogen production
in Bangladesh.