3.4. Energy demand The energy deman

3.4. Energy demand
The energy demand is also important to achieve economic efficiency and sustainability for a ground water supply system. Each function of water supply system is taken into account for calculation of energy consumption excluding water management, water treatment and water storage. Energy demand for water catchment includes electricity for pumping groundwater out of the tube-wells only as rainwater harvesting does not require electricity. For extraction of water from tube-wells eight submersible pumps are used in the tube-wells. The rated power of each pump is multiplied with the running time of the pump to determine the energy requirement. The total energy demand for water catchment is calculated to be 1,583 to 1,621 kilowatt hours per day
From the reservoirs the water is pumped by booster pumps and to different buildings. Running times of the boosters vary between 8 and 18 hours per day. The rated power is multiplied with the running time to determine energy demand and it was computed that 1,252 kWh energy is consumed per day for water distribution. 1000 kWh energy is required for sewage treatment plant. The largest part is required for the root air blowers with 434 kWh followed by the collection pumps (266 kWh per day). Another large energy demand is due to the filter pumps and the smallest part of the energy demand is caused by the chlorine dosing pumps. The treated water is pumped back to campus for irrigation purpose. This requires 230 kWh of energy. Total energy demand for the university water supply system is shown in table 2.
The energy demand per litre of demanded/supplied water is determined by combining the water consumption per day with the energy demand for the water supply and treatment. In this case study the energy demand lies at approximately 2 Wh/litre. This is the energy that has to be expended for one litre of water from the groundwater catchment through the use to the treated water for irrigation.