Compressed Air Storage Calculations: Difference between revisions
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According to the calculator, a 50 l tank of air at 3000 psi will release about 0.5kWhr via adiabatic expansion, and 2.5x this with isothermal expansion. | According to the calculator, a 50 l tank of air at 3000 psi will release about 0.5kWhr via adiabatic expansion, and 2.5x this with isothermal expansion. | ||
=Rough Calculations= | |||
*Air tools require 30 cfm for 1 hp [https://fluidpowerjournal.com/air-tool-is-inefficient/#:~:text=Typical%20Compressor%20Performance&text=An%20air%20motor%20producing%20one,shaft%20power%20at%20the%20tool.] | |||
*A 300 cuf tank thus gives 10 minutes, about, of 1 hp power. | |||
*6 cylinders would thus give 1 hp hr. | |||
=Cylinder Sourcing= | =Cylinder Sourcing= | ||
Revision as of 00:51, 9 February 2021
Calculations for a 1kWhr System
- From Compressed Air Energy Storage results, it takes 170 cubic meters of air to deliver 1kWhr of usable stored energy.
Calculator
See https://www.tribology-abc.com/abc/thermodynamics.htm
According to the calculator, a 50 l tank of air at 3000 psi will release about 0.5kWhr via adiabatic expansion, and 2.5x this with isothermal expansion.
Rough Calculations
- Air tools require 30 cfm for 1 hp [1]
- A 300 cuf tank thus gives 10 minutes, about, of 1 hp power.
- 6 cylinders would thus give 1 hp hr.
Cylinder Sourcing
- Firefighter supply - 300 cf $300 [2]
- 250 cf - $285 [3]
- 250 cf = $330 [4] K size?
- T-size 300 cf - [5]
- T goes up to 390 cf - [6]
Compressor
- Scuba compressor - $243, 1800W - [7]