House Gravity Storage: Difference between revisions
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=Calculations= | =Calculations= | ||
How much energy can you store by sloshing water from ground to roof? 7m to roof of a 2 story house. Take a 500 sf [[Rosebud]]. That gets us 100 cubic meters of water on roof in totes stacked 2 high. That is Mgh=100 cu m*7m*1000kg/cu m*10 m/s/s. 7 megajoule. Or 1.94kWhr potential energy! Pending investment in structure - this has sufficient energy! | How much energy can you store by sloshing water from ground to roof? 7m to roof of a 2 story house. Take a 500 sf [[Rosebud]]. That gets us 100 cubic meters of water on roof in totes stacked 2 high. That is Mgh=100 cu m*7m*1000kg/cu m*10 m/s/s. 7 megajoule. Or 1.94kWhr potential energy! Pending investment in structure - this has sufficient energy! | ||
=Optimization= | |||
Dig down for basement - and that is another 3 meters of height. So we are at 1.94*10/7 = 2.8 kWhr. | |||
Expand house to 1000 sf and get 5.5 kWhr storage. | |||
Now ask what the electric storage is for. If heating in winter - totes can double as heating - if excess PV is used to convert electricity to heat. | |||
=Links= | =Links= | ||
*[[Gravity Storage]] | *[[Gravity Storage]] | ||
Revision as of 05:42, 15 November 2021
Calculations
How much energy can you store by sloshing water from ground to roof? 7m to roof of a 2 story house. Take a 500 sf Rosebud. That gets us 100 cubic meters of water on roof in totes stacked 2 high. That is Mgh=100 cu m*7m*1000kg/cu m*10 m/s/s. 7 megajoule. Or 1.94kWhr potential energy! Pending investment in structure - this has sufficient energy!
Optimization
Dig down for basement - and that is another 3 meters of height. So we are at 1.94*10/7 = 2.8 kWhr.
Expand house to 1000 sf and get 5.5 kWhr storage.
Now ask what the electric storage is for. If heating in winter - totes can double as heating - if excess PV is used to convert electricity to heat.