RU55431U1 - COGENERATION POWER PLANT - Google Patents

Abstract

The solution relates to the field of power engineering and is intended for the combined generation of thermal and electric energy. Typically, in such installations, the heat of the exhaust gases of the engine and the heat from the engine cooling jacket are used to heat the coolant. The proposed solution also involves a heat exchanger for cooling the engine oil system and its water-air heat exchanger. A water supply pipe from the recovery system heat exchanger is connected to the cooling coil of the engine oil system and from which the pipe is led to the heat exchanger of the engine cooling jacket, and a supply air line is connected to its air-to-air heat exchanger and a water supply pipe through the low-temperature heat exchanger, and a water supply pipe to the cold water in front of the low-temperature circuit heat exchanger a three-way valve is installed. In the proposed power plant, the use of additional heat sources makes it possible to increase the efficiency using units. already available in the installation, as well as reduce the payback period of the installation by increasing the degree of sale of thermal energy to the consumer.

Description

The solution relates to the field of power engineering and is intended for the combined generation of thermal and electric energy.

A self-contained cogeneration power plant is known (US Pat. RF No. 2162534 F 02 G 5/02, F 02 G 1/043, F 02 B 65/00, publ. 2001.01.27). The power plant is designed for stationary and mobile facilities while generating electricity and heat. The technical result achieved is an increase in the efficiency of the installation as a whole and a decrease in its overall dimensions. During operation, the engine produces useful energy that is converted into electrical energy by means of an electric generator located on the same shaft as the engine. To cool the engine, water is supplied to the cooling jacket from external heat consumers through the return line. Heated coolant from the cooling jacket enters the exhaust gas heat exchanger-heat exchanger, where it is mixed with water coming from the line through the jumper, while it is additionally heated by the engine exhaust gases coming through the main to a high temperature. From the heat exchanger-utilizer, hot water is circulated by a circulation pump for heat supply to external heat consumers through the hot water supply line. To control the amount of water entering the cooling jacket and the heat exchanger through a jumper, control valves are provided.

However, this installation uses only heat from the engine cooling jacket and heat from the exhaust gases of the engine. Thus, the power installation capabilities are not fully utilized.

A well-known stand-alone Stirling installation for the simultaneous production of electricity and heat (US Pat. RF No. 2162532, F 02 G 5/02, F 02 G 1/02, 2001.01.27), which by the sum of the characteristics is closest to the proposed one and is essentially cogeneration .

The term cogeneration means the simultaneous production of electric and thermal energy in one process and is widely used in the power industry (see, for example, the journal Electrosystems No. 1 (10), 2005, an article by Yu.N. Petrov).

The installation comprises an engine with an electric generator on one shaft, a recovery boiler, to which a supply line for the exhaust gases of the engine is connected, a heat exchanger of the recycling system - at the outlet of the water pipe from the boiler -

heat exchanger, an engine cooling jacket heat exchanger connected by a pipeline to a recovery boiler, forming a high-temperature circuit, connected by a water supply line to a low-temperature circuit, including a first-stage hot water heat exchanger, a circulation pump and a cold water supply line, as well as control valves.

As in the above analogue, the prototype solves the problem of increasing efficiency and reducing the overall dimensions of the installation. These tasks are solved by using the heat of the engine cooling system to heat external heat consumers and the residual heat of the engine exhaust gases - for hot water supply with the generation of high pressure steam.

However, this solution also did not fully utilize the power installation capabilities, i.e. not all waste heat is used.

These shortcomings are eliminated by the proposed solution.

The task at hand is the improvement of the power plant and the reduction of its payback period by increasing the degree of sale of thermal energy.

The technical result is an increase in the efficiency of the installation due to the use of additional heat from the thermal nodes of the installation.

This technical result is achieved by the fact that in a cogeneration power plant containing an engine with an electric generator on one shaft, a recovery boiler, to which a supply line of exhaust gases of the engine is connected, a heat exchanger of the recovery system - at the outlet of the water pipe from the recovery boiler, an heat exchanger of the engine cooling jacket, connected by a pipeline to a recovery boiler, forming a high-temperature circuit, connected by a water supply line to a low-temperature circuit, including a heat exchanger about the water supply of the first stage, the circulation pump, the cold water supply line, as well as the control valves, the heat exchanger for cooling the oil system of the engine is additionally introduced into the high-temperature circuit, to which the water supply pipe from the heat exchanger of the recovery system is connected and from which the pipeline is led to the heat exchanger of the engine cooling jacket, and a water-air heat exchanger for cooling the engine charge air, to which the master is connected, is additionally introduced into the low-temperature circuit s charge air supply and water supply conduit of the heat exchanger low-temperature loop, and

The cold water supply line has a three-way valve in front of the low-temperature circuit heat exchanger.

The inclusion of an engine oil system and a water-air heat exchanger in the heat exchanger system makes it possible to fully utilize the heat of the high-temperature and low-temperature cooling circuits of the installation, and heat energy is utilized in the heat exchanger of the low-temperature circuit (water temperature 32-34 ° C), which is released into the environment in a standard installation by cooling towers.

The installation of a three-way valve on the line for supplying cold water to the heat exchanger of the low-temperature circuit allows you to maintain the set temperature of the water entering to cool the charge air into the water-air heat exchanger of the engine.

The proposed cogeneration power plant is shown in the drawing.

The installation comprises a gas engine 1 with an electric generator 2 on the same shaft as engine 1. The exhaust gases of engine 1 enter the recovery boiler 3 via line 4. At the outlet of the recovery boiler 3, a plate heat exchanger 5 is installed (a hot water heat exchanger of the second heating stage) of the recovery system communicated by the pipeline 6, on which the circulation pump 7 is installed, with the recovery boiler 3. A recovery pipe 8 from the heat exchanger 9 of the engine cooling jacket 1 is connected to the recovery boiler 3. These units form high-temperature th motor circuit 1, connected to the low-temperature circuit by a pipe 10, the low-temperature circuit of the engine 1 includes a plate heat exchanger 11 (a hot water supply heat exchanger of the first heating stage), which is connected by a pipe 12 to a water-air heat exchanger 13 of the engine 1. Together with the pipe 14, on which is installed circulation pump 15, it forms the water circuit of the heat exchanger 11. Inflated air to the water-air heat exchanger 13 is connected via line 16. Cold water enters the line 17, on which a three-way valve 18 is installed, which allows part of the water through line 19 to be diverted to the heat exchanger 11, the heated water line 20 goes to the bypass line 21 from the latter.

A heat exchanger 22 for cooling the oil system of the engine 1 is additionally introduced into the high-temperature circuit of the power plant, to which a water supply pipe 23 is connected from the heat exchanger 5 of the recycling system, and from which the pipe 24 is led out to the heat exchanger 9 of the engine cooling jacket 1.

Cogeneration power plant operates as follows.

During operation, engine 1 produces useful energy that is converted into electrical energy using an electric generator 2, while the thermal energy from the cooling systems of engine 1 and the waste heat boiler 3 is used to heat the hot water supply network, which is supplied to consumers via line 25 by pump 26.

Cold water through line 17 through a three-way valve 18 enters the heat exchanger 11 of the low-temperature circuit in the amount necessary to maintain water (pipe 12) at the inlet to the air-water heat exchanger 13 with a predetermined temperature of 32 ° C. The rest of the water through the bypass line 21, mixed with water from the line 20 after the heat exchanger 11 of the low-temperature circuit through a pipe 10 is fed to the heat exchanger 5 of the disposal system.

The cooled coolant of the low-temperature circuit with a temperature of 32 ° C from the heat exchanger 11 through the pipe 12 enters the water-air heat exchanger 13, in which it is heated to 34 ° C and through the pipe 14 through the circulation pump 15 is again fed to the heat exchanger 11.

The heat carrier of the high-temperature circuit from the heat exchanger 5 is fed through a pipe 23 to a heat exchanger 22, then through a line 24 - to a heat exchanger 9 of the engine cooling jacket 1 and through a pipe 8 it enters a heat recovery boiler 3, from which, by means of a circulation pump 7, it passes through a pipe 6 to a system heat exchanger 5 recycling. The exhaust gases from the engine 1 enter the waste heat boiler 3 via line 4, and then to the heat exchanger 5, from where the thermal energy goes to the consumer.

In the proposed power plant, the use of additionally utilized energy makes it possible to increase the efficiency and reduce the payback period of the plant by increasing the degree of sale of thermal energy, since at the same gas flow rate, the sale of thermal energy to the consumer increases.

Claims (1)

A cogeneration power plant containing an engine with an electric generator on one shaft, a recovery boiler, to which an engine exhaust gas supply line is connected, a heat exchanger of the recovery system at the outlet of the water pipe from the recovery boiler, an engine cooling jacket heat exchanger connected by a pipeline to the recovery boiler, forming a high-temperature a circuit connected by a water supply line to a low-temperature circuit including a first-stage hot water heat exchanger circulating on os, a cold water supply line, as well as control valves, characterized in that a heat exchanger for cooling the oil system of the engine is additionally introduced into the high-temperature circuit, to which a water supply pipe is connected from the heat exchanger of the recovery system and from which the pipeline is led out to the heat exchanger of the engine cooling jacket, and low-temperature circuit additionally introduced a water-air heat exchanger for cooling the engine’s charge air, to which the charge air supply line is connected and a pipeline for supplying water from the heat exchanger of the low-temperature circuit, and a three-way valve is installed on the cold water supply line in front of the heat exchanger of the low-temperature circuit.