Исследование термодинамической эффективности микроТЭЦ с газовой микротурбиной измененной очередности процессов

Е.Г. Липихин, Д.В. Шевелев

Инженерный журнал: наука и инновации

# 10·2016

Thermodynamic efficiency investigation

for a micro-CHP system featuring a gas microturbine

with an altered process sequence

Bauman Moscow State Technical University, Kaluga branch,

Kaluga, 248600, Russia

We consider a cogeneration plant featuring a gas microturbine with an altered process

sequence. We describe the flow diagram of our plant, its principle of operation and pri-

mary advantages: high heat energy conversion efficiency, fuel combustion at atmospheric

pressure, absence of either a combustion chamber proper or a high-temperature micro-

turbine gas-to-air heat exchanger. We supply thermodynamic parameter calculation

results for our diagram operating in both traditional and low-temperature heating sys-

tems. Analysis of the results obtained shows that this cogeneration plant is feasible and is

able to satisfy heating and electricity demands with microturbine parameters being char-

acteristic of commercial centrifugal compressors used in conjunction with internal com-

bustion engines. As a conclusion, we select the optimum microturbine pressure ratio to

be π

= 1.6…1.8, since it achieves a high micro-CHP thermal output with acceptable micro-

turbine parameters.

Keywords:

micro-CHP, reverse Brayton cycle, gas microturbine.

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