This paper presents the use of solar energy for generation of electrical energy through solar pho-tovoltaic (SPV) system to meet the load requirement of a domestic building. Complete design and economic analysis of SPV system for different costs of SPV module is done and compared with grid electricity for with and without storage conditions. The results of the study encourage the use of SPV system for a residential building and show that SPV system is an economically viable option to meet the exponentially growing electricity requirement for household applications in India.
India faces a significant gap between electricity demand and supply. Demand is increasing at a very rapid rate compared to supply. According to the World Bank, roughly 40% of residences in India are without electricity. In addition, blackouts are a common occurrence throughout the country. The World Bank also reports that one- third of Indian businesses believe that unreliable electricity is one of their primary impediments of doing business. In addition, coal shortages are further straining power generation capabilities. In order to meet the situation, a number of options are considered. Power generation from freely available solar energy is one such option. Most parts of India receive bright sunshine around 3000 hours in a year except Kerala, northeastern states and Jammu & Kashmir where sunshine hours are appreciable low.
During monsoon, a significant decrease in sunshine occurs over the whole country except Jammu and Kashmir where the maximum duration of sunshine occurs in June and July, and minimum during January due to its location. The northeastern states and southeast peninsula also receive relatively less sunshine during October and November due to the northeast monsoons. As far as the availability of global solar radiation is concerned, more than 2000 kWh/m2/year are received over Rajasthan and Gujarat, while east Bihar, northwest Bengal and the northeastern states receive less than 1700 kWh/m2/year. The availability of diffuse solar radiation varies widely in the country. The annual pattern shows a minimum of 740 kWh/m2/year solar radiations over Rajasthan increasing eastwards to 840 kWh/m2/year in the north eastern state, and southwards to 920 kWh/m2/year.
India is thus endowed with rich solar energy resource. The average intensity of solar radiation received in India is 200 MW/km2. With a geographical area of 3.287 million km square, this amounts to 657.4 million MW. However, 87.5% of the land is used for agriculture, forests, etc., 6.7% for housing, industry, etc. and 5.8 % are barren, snowbound or generally inhabitable. Thus only 12.5% of the land area amounting to 0.413 million km square, in theory, can be used for solar energy installations. Even if 10% of this land can be used, the available solar energy would be 8 million MW, which is equivalent to 5909 million tons of oil equivalent.
Launching India’s national action plan on climate change on June 30, 2008, the prime minister of India Dr. Manmohan Singh stated “Our vision is to make India’s economic development energy efficient. Over a period of time, we must pioneer a graduated shift from economic activity based on fossil fuels and from reliance on non-renewable and depleting sources of energy to renewable sources of energy. In this strategy, the sun occupies centre-stage, as it should being literally the original source of all energy. We will pool our scientific, technical and managerial talents, with sufficient financial resources, to develop solar energy as a source of abundant energy to power our economy and to transform the lives of our people. Our success in this endeavor will change the face of India. It should also enable India to help change the destinies of people around the world.”
The economic viability of a standalone PV system in comparison to the most likely conventional alternative system, i.e. a diesel-powered system, has been analyzed for energy demand through sensitivity analysis [
A methodology is presented [
Techno-economic feasibility of three different energy-supplying alternatives, namely the solar photovoltaic (SPV) system, diesel generator system and extending the grid connection for energy supply to a remote village located around 15 km away from the place where grid supply is available, is suggested [
Literature presents several studies on energy payback time and life cycle analysis of PV technologies. The analyses of the PV system with reference to a fuel oil-fired steam turbine and their GHG emissions and costs revealed that greenhouse gases (GHG) emission from electricity generation from the PV system is less than one-fourth that from an oil-fired steam turbine plant and one half that from a gas-fired combined cycle plant. From the life cycle energy use and GHG emission perspectives, the PV system is a good choice of power generation. However, it also indicates that large scale exploitation of PV could lead to other types of undesirable environmental impacts in terms of material availability and waste disposal [
Life cycle assessment of electricity generation by PV panels considering mass and energy flows over the whole production process starting from silica extraction to the final panel assembling, using the most advanced and consolidate technologies for polycrystalline silicon panel production is presented [
A techno-economic analysis of standalone solar photovoltaic system has been presented [
A techno-economic comparison of rural electrification based on solar home systems and PV micro-grids to supply electricity to rural community for domestic purpose has been performed [
A strong case of standalone SPV systems has been built by conducting feasibility study in an island of West Bengal India by the name Sagar Deep based on socio-economic and environmental aspects. The generation costs of SPV systems and conventional power has been compared to show how conventional power systems suffer from diseconomy when power needs to be transmitted to extremely remote locations. The social viability of SPV was apparent from a conspicuous improvement in commerce, trade, education and increased participation of women in activities other than household chores in the island [
The paper uses the solar radiation data of a particular site for complete design and cost analysis of proposed Solar Photovoltaic (SPV) systems, to be installed in a building to supply electricity.
The main electrical loads necessary for improving living conditions in the village are: household appliances (lighting, TV, refrigerator, washing machine, water pump, electric iron and fan, AC). The ratings of these appliances are given in
Solar radiation data provide information on how much of the sun’s energy strikes a surface at a location on earth during a particular time period. These data are needed for effective research into solar energy utilization.
The daily average solar energy incident over India varies from 4 to 7 kWh/m2 with about 1500 - 2000 sunshine hours per year, depending upon location. Theoretically, a small fraction of the total incident solar energy
Electrical Load | No. of Units | Operating Hours Per Day | Wattage Per Unit Used | Total Units Consumed Per Day |
---|---|---|---|---|
Lighting Lamp | 5 | 4 lamps from 18 to 24 & 1 lamp from 0 to 6 | 60 | 1.8 |
Washing Machine | 1 | from 11 to 13 | 250 | 0.5 |
Refrigerator | 1 | from 0 to 24 | 180 | 2.4 |
Water Pump | 1 | For three hours daily | 120 | 0.36 |
TV | 1 | from 17 to 24 | 80 | 0.56 |
Fan | 3 | from 0 to 24 | 60 | 1.44 |
Electric Iron | 1 | For one hour in two days | 1500 | 0.75 |
AC 1.5 ton | 2 | 6 hours each daily | 2000 | 24 |
Total | 6530 Watts | 31.81 |
(if captured effectively) can meet the entire country’s power requirements. In view of this, measuring efficiently solar energy radiations in a big country like India and preparing data for various applications are major challenges. The network of solar energy measuring stations is rather scarce throughout the world. In India, only IMD (Indian Meteorological Department) Pune provides data for quite few stations, which is considered as the base data for research purposes. However, hourly measured data of solar irradiance is not available, even for those stations where measurement has already been done. Due to lack of hourly measured data, the estimation of solar energy at the earth’s surface is an important study in the present scenario to meet the energy requirement from green energy sources. Monthly averaged data of global and diffuse solar irradiance at New Delhi is shown in
The schematic diagram of a PV power system with battery storage is presented in
In
1) Sizing of the PV generator
The most appropriate SPV power system to cover such a load is illustrated in
The peak power of the PV generator (
where
Substituting these values in the above equation, we obtain the peak power of the PV generator:
To install this power, a mono-crystalline PV module type MBPV-CAAP (this module is of Moser Baer company) of a gross area of
No. of modules in series
Hence the number of modules in parallel = 4
For MBPV CAAP 200 Wp module
Now, we obtain an open circuit voltage and short circuit current for this SPV array as
2) Sizing of the Battery Block
The storage capacity of battery block for such systems is considerably large. Therefore, special lead-acid battery cells (block type) of long life time, high cycling stability-rate and capability of standing very deep discharge should be selected. Such battery types are available but at much higher price than regulars batteries. The ampere hour capacity
where
3) Design of the Battery Charge Controller
The battery charge controller is required to safely charge the batteries and to maintain longer lifetime for them. It has to be capable of carrying the short circuit current of the PV array. Thus, in this case, it can be chosen to handle 31 A.
4) Design of the Inverter
The used inverter must be able to handle the maximum expected power of AC loads. Therefore, it can be selected as 20% higher than the rated power of the total AC loads. Thus the rated power of the inverter becomes 7836 W. The specifications of the required inverter will be 7836 W, 220 VAC, and 50 Hz.
The cost of the equipments required in the proposed SPV system is presented in
In this section the life cycle cost (LCC) estimation of the designed standalone PV system is discussed. The LCC
Item | PV | Battery Cell for 510 Ah | Charger | Inverter | Installation | M&O/Year |
---|---|---|---|---|---|---|
Cost | Rs. 60/Wp | Rs. 5500/cell | Rs. 258/A | Rs. 36/W | 10% of PV cost | 2% of PV cost |
of an item consists of the total costs of owning and operating an item over its lifetime, expressed in today’s money.
The costs of a standalone SPV system include acquisition costs, operating costs, maintenance costs, and replacement costs. All these costs have the following specifications:
・ The initial cost of the system (the capital cost) is high.
・ There are no fuel costs.
・ Maintenance costs are low.
・ Replacement costs are low (mainly for batteries).
The LCC of the PV system includes the sum of all the present worths (PWs) of the costs of the PV modules, storage batteries, battery charger, and inverter, the cost of the installation, and the maintenance and operation cost (M&O) of the system. The details of the used cost data for all items are shown in
The lifetime N of all the items is considered to be 25 years, except that of the battery which is considered to be 5 years. Thus, an extra 4 groups of batteries (each of 6 batteries) have to be purchased, after 5 years, 10 years, 15 years and 20 years assuming inflation rate i of 3% and a discount or interest rate d of 10%. Therefore, the PWs of all the items can be calculated as follows [
PV array cost
Initial cost of batteries cells
The PW of the 1st extra group of batteries (purchased after
The PW of the 2nd extra group of batteries (purchased after
Charger cost
Inverter cost
Installation cost
Operation and maintenance cost per year = Rs. 10560
The PW of the maintenance cost CMPW can be calculated to be Rs. 125355.5, using the maintenance cost per year (M/yr) and the lifetime of the system (
Therefore, the LCC of the system can be calculated, to be Rs. 2613054, from:
It is sometimes useful to calculate the LCC of a system on an annual basis. The annualized LCC (ALCC) of the PV system in terms of the present day Rupees can be calculated, to be Rs. 206116.8/yr, from,
Once the ALCC is known, the unit electrical cost (cost of 1 kWh) can be calculated, to be Rs. 17.5/kWh, from:
Now, using the same procedure as given above, the cost of the PV system without batteries can be calculated by excluding the terms
The unit cost of electricity for with and without batteries for different rates of PV modules is calculated using the same procedure as above and tabulated in
The cost of electricity generated from solar photovoltaic system with batteries is calculated to be Rs. 22/kWh, whereas the cost of utility electricity supplied to consumers is approximately Rs. 6.8/kWh for domestic purpose. However, the cost of electricity generated from solar photovoltaic is decreasing rapidly as the initial cost of PV modules is coming down with time as shown in
As shown in
Year | PV Panel Cost/Wp | Unit Cost of Electricity (INR) | Unit Cost of Electricity (INR) | ||
---|---|---|---|---|---|
With Battery | Without Battery | ||||
Without Subsidy | With 30% Subsidy | Without Subsidy | With 30% Subsidy | ||
2007 | 150 | 28 | 19.6 | 17 | 11.9 |
2012 | 100 | 22 | 15.4 | 11 | 7.7 |
2017 | 60 | 18 | 12.6 | 7 | 4.9 |
2022 | 40 | 15 | 10.5 | 4 | 2.8 |
creasing day by day, presently it is around Rs. 6.8/unit for domestic use. But in the near future, the cost of electricity generated from conventional fuels in India is expected to increase to around four times than its present value due to the rapid increase in the conventional fuel prices but the cost of unit electricity generated from SPV is decreasing as shown above. Hence SPV systems are expected to be a cheaper and good option for its use in residential purpose in the near future. Therefore the present results reflect the first order indication to energy planners in the near future. Hence the SPV power generation will be economically comparable to the grid connected power supply in the near future in India.
Proper utilization of renewable energy sources is very important worldwide especially in the developing countries like India. This study presents the complete design and the life cycle cost analysis of the PV system for single household application. The results of the study indicate that electrifying a single area household using PV systems is beneficial and suitable for long-term investments, because the initial prices of the PV systems are decreasing as the cost of PV panels is decreasing.
In this paper an electrification study for a single residential household is carried out using a standalone SPV system. The results of study reveal that although at present, the cost of electricity generated from SPV system is relatively high as compared to grid electricity but in the near future the cost of electricity from SPV systems will decrease rapidly and cost of electricity from grid is likely to increase. Also, the efficiency of the solar cells is increasing day by day which will make it further economical. As we know that solar power is one of the most promising and more predictable sources than other renewable sources and less vulnerable to change in seasonal weather. Whereas, generation of power from other renewable sources is limited to sites where these resources exist in sufficient quantities and can be harnessed, solar energy can produce power at the point of demand in both rural and urban areas. Hence, photovoltaic systems are considered as the most promising energy sources for these sites due to their high reliability and safety. Therefore, SPV system would be the better option for household electrification in India in the near future.