The cold water that is put into a water heating device can be preheated using the reclaimed
thermal energy from a shower so that the input water does not need as much energy to be heated before being used in a shower, dishwasher, or sink. The water entering a
storage tank is usually close to 11 °C (52 °F) but by recovering the energy in the hot water from a bath or dishwasher, the temperature of the water entering the
holding tank can be elevated to 25 °C (77 °F), saving energy required to increase the temperature of a given amount of water by 14 °C (57 °F). This water is then heated up a little further to 37 °C (99 °F) before leaving the tank and going to the average shower. When recycling water from a bath (100–150 litres) or shower (50–80 litres) the waste water temperature is circa 20–25 °C. An in-house
greywater recycling tank holds 150–175 litres allowing for the majority of waste water to be stored. Utilizing a built in copper
heat exchange with
circulation pump the residual heat is recovered and transferred to the cold feed of a combi-boiler or hot-water cylinder, reducing the energy used by the existing
central heating system to heat water. There are three categories in which waste heat may be categorized into: Low-grade waste heat (less than 100 °C), Medium-grade waste heat (100-400 °C), and High-Grade waste heat (greater than 400 °C). While all of these can be converted into energy, medium-grade waste heat is the most common in household applications. Waste heat from common home applications can also be used to convert salty water into clean, drinkable water. Although this process is only in the beginning of its development, it shows strong promise for the future of clean water and energy efficiency. This process of
desalination could be the future of clean water across the globe. Because this process uses so much energy, it could be used in conjunction with water heat recycling to reduce energy costs. ==Impact and cost==