The concept of creating use of of solar warm h2o processes arise from the need to convert or replace the production processes of different industries, which minimizes production costs and reduces CO2 emissions. This story shall discuss how to use solar warm h2o system within the wine industry. The wine sector is a huge business that uses many of h2o for sterilizing and for fermenting processes. Consequently the actual price of h2o is cheap, the life used to heat the h2o whether it is electric, natural gas, oil or wood is getting more expensive. That is why the use of solar warm h2o processes like the SolarBeam is of interest to wineries seeing to reduce life usage.
Sequential to understand how the SolarBeam can reduce operational costs, we need to understand the wine industry. There exists stages within the winemaking process, where it is compulsory to maintain little temperatures for storing supplies. These cooling processes are characterized by high life usage and h2o consumption, and the toxicity of refrigerants. On the other hand,solar warm h2o heating is wanted for disinfection. Within the cellars, as in any food industry, it is compulsory to maintain sanitary conditions.
Cleaning and disinfection of machinery and buildings requires the use of large volumes of warm water. As discussed above the large no. of warm h2o used for cleaning equipment, tanks, bottles, etc. is usually heated by combustion boilers that make large no. of gases that contribute to global warming.
In addition, together with the cost fluctuations occurring for conventional fuels, it is becoming increasingly well-known to reduce costs by creating use of technologies for example solar thermal This takes advantage of solar life to heat the h2o at high temperatures, up to 95 C 204 F, sufficient for use in such processes, like sterilization. Since technologies like SolarBeam can track the sun, different h2o temperatures should be maintained due to the fact that the system can stop tracking the sun once the desired h2o heat was reached. Through the use of a heat exchanger, different warm h2o tanks can save heat at different temperatures and the SolarBeams should be programmed to heat the h2o until the desired heat was reached. This kind of flexibility is not available with flat panels due to the fact that they cannot rotate and they cannot stop collecting energy, due to the fact that they cannot be moved or covered. For applications that want h2o temperatures above 65 C, technologies like the SolarBeam can release payback of approximately seven years, depending on the kind of solar radiation available.
In contrast, flat panels for the similar to project should be closer to a 20 year payback and evacuated tube, 15 years. To look what the direct solar radiation is in your area, leave to to look an interactive map.
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