On the Higher Compressed Air Supply and New Haulage System at Tochibora, Kamioka Mines

Abstract The article presents a mathematical model describing the operation of a piston pneumatic air engine. Compressed air engines are an alternative to classic combustion solutions as they do not directly emit toxic exhaust components. In the study, a modified internal combustion piston engine was adopted as pneumatic engine. The mathematical model was divided on the two subsystems, that is, mechanical and pneumatic. The mechanical subsystem describes a transformation of compressed air supply process parameters to energy transferred to the piston and further the conversion of the translational to rotary motion; in turn, in the pneumatic part, the lumped elements method was used. Calculations were carried out using the Matlab-Simulink software, resulting in the characteristics of external and economic indicators. The presented mathematical model can be ultimately developed with additional elements, such as the intake or exhaust system, as well as timing system control.

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Investigation on improving the thermal efficiency of a mini boiler fired with straight vegetable oils

Thermal Science ◽

10.2298/tsci180126243p ◽

2020 ◽

Vol 24 (2 Part A) ◽

pp. 713-722

Author(s):

Maran Punnaivanam ◽

Arumugam Krishnan

Keyword(s):

Vegetable Oils ◽

Rice Bran ◽

Thermal Efficiency ◽

Sunflower Oil ◽

Rice Bran Oil ◽

Supply System ◽

Compressed Air ◽

Exhaust Gases ◽

Oil Blends ◽

Air Supply

In the present work, straight sunflower oil and rice bran oil blended with diesel have been used as fuel diesel in a mini boiler. The thermal efficiency of the boiler and emission levels in the exhaust gases have been investigated by burning the oil blends of varying proportions ranging from 0-50%. An additional air supply system and compressed air atomization of fuel with a new burner have been used to improve the thermal efficiency of the mini boiler. Results revealed that the addi?tional air supply improved the thermal efficiency up-to 7% and reduced the CO and HC emission up-to 40%. The use of compressed air atomization further increased the thermal efficiency up-to 4% and reduced the CO and HC emission up-to 70%.

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Rippling mattress worked from compressed air supply.

Archives of Disease in Childhood ◽

10.1136/adc.46.249.733 ◽

1971 ◽

Vol 46 (249) ◽

pp. 733-735

Author(s):

A H Etchells ◽

D L Thomas ◽

D G Young

Keyword(s):

Compressed Air ◽

Air Supply

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Ocean Energy On-Demand Using Underocean Compressed Air Storage

Volume 5: Ocean Space Utilization; Polar and Arctic Sciences and Technology; The Robert Dean Symposium on Coastal and Ocean Engineering; Special Symposium on Offshore Renewable Energy ◽

10.1115/omae2007-29515 ◽

2007 ◽

Cited By ~ 8

Author(s):

Richard J. Seymour

Keyword(s):

Constant Pressure ◽

Low Cost ◽

Salt Dome ◽

Compressed Air ◽

Recovery Efficiency ◽

Ocean Energy ◽

On Demand ◽

Storage Chamber ◽

Air Supply ◽

Design Challenge

Renewable ocean energy sources are typically highly variable and uncontrolled, resulting in the production of low value electricity. Storing energy in the form of compressed air is a mature technology on land. Utilizing hydrostatic pressure at depth in the ocean to maintain constant pressure in the air supply chamber offers large recovery efficiency advantages. If salt dome caverns are not available, the design challenge is the development of a low cost bottom-founded air storage chamber.

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