EA029633B1 - Device for conversion of thermal energy to electric energy - Google Patents

Abstract

The proposed invention is related to thermal engineering, in particular, to devices for conversion of thermal energy to electric energy. The provided device comprises a pump unit, a heat-exchange unit, a compressor unit, a ventilation unit, an ammonia unit, a crankshaft unit, an electric power generation unit, and a second pump unit. In the proposed device, the first outlet of the heat-exchange unit is connected to the inlet of the ventilation unit, the outlet of the ventilation unit is connected to the inlet of the ammonia unit, the output of the latter is connected to the first inlet of the compressor unit, the first outlet of the compressor unit is connected to the inlet of the pump unit, and the pump unit outlet is connected to the first inlet of the heat-exchange unit, and the second inlet of the heat-exchange unit is connected to the second outlet of the compressor unit, and its second inlet is connected to the outlet of the second pump unit, and the inlet of the second pump unit is connected to the second outlet of the heat-exchange unit, the third outlet of the compressor unit is connected to the inlet of the crankshaft unit, and the outlet of the crankshaft unit is connected to the inlet of the electric power generation unit.

Description

The invention relates to heat engineering, and more specifically to devices for converting thermal energy into electrical energy. The proposed device includes a pumping unit, a heat exchange unit, a compressor unit, a ventilation unit, an ammonia unit, a crankshaft unit, an electric power generation unit, and a second pumping unit. In the proposed device, the first output of the heat exchange unit is connected to the input of the ventilation unit, its output to the input of the ammonia unit, the output of which is connected to the first input of the compressor unit, the first output of the compressor unit is connected to the input of the pumping unit, and its output to the first input of the heat exchange unit. The second input is connected to the second output of the compressor unit, and its second input is connected to the output of the second pumping unit, and its input is connected to the second output of the heat exchange unit, and the third output of the compressor unit It is connected to the input of the crankshaft unit, and its output is connected to the input of the electric power generation unit.

029633 Β1

029633 Β1

029633

The invention relates to the field of thermal energy, and more specifically to devices for converting thermal energy into electrical energy.

A device for converting thermal energy into electrical energy is known (see: Avt.SV.S. № 622193, publ. 30.08.1978; Bulleteni № 32)

The known converter of thermal energy into electrical having a turbo-electric generator, a closed circuit electrically conductive in the liquid phase of the working fluid, such as potassium, a steam generator, a condenser and an electromagnetic pump, a closed loop of the working fluid is made together with a steam generator, a condenser and an electromagnetic pump in the form of an electromagnetic heat pipe in the right channel which installed the turbine and the rotor of the generator, while the rotor is located between the poles of the magnetic system of the electromagnetic heat pipe.

The specified known device is taken as an analogue of the present invention.

The disadvantages of the known device are its complexity and low reliability.

It is also known a device for obtaining energy from the heat of water (see Application: CI No. 2003 109700, published on January 20, 2005), which is taken as a prototype of the present invention.

The known device consists of a carbon dioxide turbine, a liquid pump, an ammonia compressor, a reactive ammonia turbine, a flow water pipe, radiators and heat exchangers, where the outlet from the ammonia compressor is connected to an ammonia heat exchanger for ammonia vapor, the outlet from which is connected to the inlet of the ammonia reactive a turbine, the outlet of which is connected to the ammonia boiling radiator, the outlet of which is connected with the entrance to the ammonia compressor, the output of their carbon dioxide liquid high pressure pump It is connected to a carbon dioxide boiling radiator carbon dioxide, the outlet of which is connected to the carbon turbine inlet, the outlet of which is connected to the carbon dioxide condensation radiator of carbon dioxide vapor, the outlet of which is connected to the entrance to the carbon dioxide high pressure pump, energy consumer, carbon dioxide turbine, carbon dioxide high pressure liquid pump, ammonia compressor, reactive ammonia turbine are all installed on the same shaft.

The disadvantage of this device is its complexity and low reliability.

The aim of the invention is to simplify it and increase reliability.

This goal is achieved by a device for converting thermal energy into an electrical pumping unit, a heat exchange unit and a compressor unit, characterized in that it includes a ventilation unit, an ammonia unit, a crankshaft unit, an electric power generation unit and a second pumping unit, where the first the output of the heat exchange unit is connected to the input of the ventilation unit, its output to the input of the ammonia unit, its output to the first input of the compressor unit, the first output of the compressor unit is connected to the input of the pump unit unit and its output to the first input of the heat exchanger unit, and its second input is connected to the second output of the compressor unit, and its second input is connected to the output of the second pumping unit, and its input is connected to the second output of the heat exchanger unit, and the third output of the compressor unit is connected to the input of the crankshaft unit, and its output to the input of the electric power generation unit.

The figure shows a block diagram of the proposed device for converting thermal energy into electrical energy.

1 - heat transfer unit;

2 - ventilation unit;

3 - ammonia block;

4 - compressor unit;

5 - crankshaft unit;

6 — electric power generation unit;

7 - pump unit;

8 - the second pumping unit;

In the proposed device, the first output of the heat exchange unit is connected to the input of the ventilation unit, its output to the output of the ammonia unit, its output to the first input of the compressor unit, the first output of the compressor unit is connected to the input of the pumping unit, and its output to the first output of the heat exchange unit, and its second the input is connected to the second input of the compressor unit, and its second input is connected to the output of the second pumping unit, and its input is connected to the second input of the heat exchange unit, and the third output of the compressor unit is connected to the input of the crankshaft unit, and its output to the output of the electric power generation unit.

The proposed device works as follows. The ventilation unit 2 starts up. Due to its start-up, the evaporated ammonia gas of ammonia water enters the inlet of the ventilation unit 2 together with the inert gas from the first outlet of the heat exchange unit 2 to the second inlet of the ventilation unit 2. The ammonia gas together with the inert gas from the second outlet of the ventilation unit enters the third ammonia unit inlet 3. Ammonia gas and inert gas in ammonia unit 3 are mixed with each other, then the mixture of these gases enters the first inlet of the compressor unit 4. Ammonia solution from the first inlet of the compressor Foot pump unit 4 at the input of the unit 7 and then its output is supplied to a first input of heat exchange unit 1. From the second output of the compressor unit 4, an inert gas translational 1 029 633

At the second output of the heat exchange unit 1, inert gas to dissolve ammonia gas is fed to the input of the second pumping unit 8. From the output of the second pumping unit 8, the inert gas flows to the second input of the compressor unit 4. Since the third output of the compressor unit 4 is connected to the input of the crankshaft unit 5 by means of pistons (not shown in Fig. 1) of the compressor unit 4, the crankshaft unit 5 is actuated. The capacity of the crankshaft unit 5, as it is connected to the input of the electric generation unit nical energy, the latter is driven thereby produces electrical energy. At the top in the manner described, the operation of the device is repeated. The present invention in comparison with the known similar devices has smaller dimensions, has a simple design, which reduces its cost and increases its reliability.

Claims (1)

CLAIM A device for converting thermal energy into electrical energy, including a pumping unit, a heat exchange unit and a compressor unit, characterized in that a ventilation unit, an ammonia unit, a crankshaft unit, an electric power generation unit and a second pump unit, where the first output of the heat exchanger unit is connected, are inserted to the input of the ventilation unit, its output to the input of the ammonia unit, its output to the first input of the compressor unit, the first output of the compressor unit is connected to the input of the pumping unit, and its output to the first input is its second input is connected to the second output of the compressor unit, and its second input is connected to the output of the second pumping unit, and its input is connected to the second output of the heat exchange unit, the third output of the compressor unit is connected to the input of the crankshaft unit, and its output to the input of the power generation unit.