UA16866U - Installation for combined production of thermal and electric energy - Google Patents

Abstract

The installation for combined production of thermal and electric energy includes compressor, combustion chamber, gas turbine with electric generator, boiler-utilizer, system of pipelines and gas ducts, cogeneration equipment, system of automation and control. The installation additionally has regenerator, gas-water heat exchanger for hot water supply, system for control of combustion products.

Description

Description of the invention

The useful model applies to communal and industrial heat energy and can be used for 2 combined production of heat and electricity in communal and industrial heat supply systems.

The combined production of thermal and electrical energy has long been used in centralized heat and power supply (CHP) (1, 21.

The disadvantage of these installations is the high capital cost. In addition, they are characterized by disadvantages associated with 710 Centralized energy supply (large losses in heat and electricity networks, concentrated emissions of harmful substances, insufficient reliability of heat and electricity supply, high tariffs for electricity and heat energy).

In recent years, combined energy production (cogeneration technologies) has spread to communal heat supply and heat supply of industrial enterprises. Cogeneration technologies in communal 72 heat supply are based on the use of heat engines with electric generators, technologically connected to heating boiler units. The use of cogeneration technologies is associated with an increase in the reliability of heat and electricity supply and a significant economic effect, which is due to the rejection of expensive network electricity for the enterprises' own needs, a reduction in the need for fuel for heat supply, and the possibility of selling a surplus of produced cheap electricity to the network.

The progenitors of cogeneration plants in the communal thermal power industry and at industrial enterprises were cogeneration plants created on the basis of gas turbine plants (GTU).

There are known cogeneration plants based on gas turbines with the discharge of combustion products from gas turbines into furnaces of heating boilers with combustion of additional fuel in their medium |Z, 4).

The disadvantage of these installations is insufficient study of furnace processes when using combustion products with 29 GtTU as an oxidizer, which leads to a decrease in the efficiency and reliability of boiler operation. The disadvantage is, in many (certain) cases, the unsatisfactory condition of the heating boilers, a large number of which are outdated with a used operating resource and unsatisfactory efficiency. The disadvantage is the difficulty of solving the problem of constant hot water supply, which is connected with the seasonal operation of the heating boilers of the communal boiler house.

In recent years, cogeneration units, which are delivered together with a boiler-utilizer, have become widespread. at

This is explained by their simpler application and installation technology, compactness, the possibility of using gas-piston engines in heat engines, along with GTU, which significantly expands the powerful range of cogeneration plants, their greater maneuverability. A cogeneration plant with a waste boiler works autonomously and connected with the general technological scheme of the boiler room only by the target coolant. Ge)

There are well-known cogeneration units based on gas-piston engines (GPD) with recovery boilers, which are used in small and partly medium-capacity boiler houses 5-71. --

The disadvantage of these units is the limitation of their power range and unsatisfactory environmental characteristics (high emissions of MOX and CO (up to 500 mg per cubic meter of combustion products)), which limits their use in densely populated areas and resort areas, insufficient thermal power, which causes the need for "Heat supply additionally uses heating boilers, often with unsatisfactory efficiency and with 70% overconsumption of fuel. c A well-known cogeneration plant based on a gas turbine engine with a heat recovery boiler, selected as a prototype,

From" which is used in boiler houses of medium and high capacity of communal and industrial enterprises |8). In this installation, the gas turbine engine operates on a simple cycle. Combustion products are fed from the GTU to the recovery boiler, after which they enter the chimney. These installations meet a wide range of thermal and electrical loads of utility power and industrial enterprises. The thermal power of a cogeneration plant based on gas turbines is significantly greater than that of plants based on gas turbines and for utility companies

Ge"), its increase is not limited in principle. Installations on the basis of GTU have relatively low harmful emissions (emissions of MOH and CO in many cases are significantly less than 25-50 mg/m? of combustion products) and do not pose an environmental problem. (o) 50 The fundamental disadvantage of these installations is the unsolved problem of the year-round operation of the gas turbine in

Ф nominal mode, which is associated with the seasonality of heat energy consumption. In the summer period, unnecessary heat energy has to be discharged into the air, which leads to increased thermal pollution of the surrounding environment, and the use of a single-cycle gas turbine installation only as an electricity generator is not efficient enough. This forces utility companies to choose the capacity of 99 cogeneration plants based only on the heat capacity required for hot water supply, which is practically constant all year round. This ensures the most acceptable payback period for the installation. But this reduces the efficiency of using cogeneration technologies, because it is in winter, when the need for thermal energy is the highest, that the efficiency of using these technologies, related to saving fuel for the production of thermal energy, is the highest. because In the useful model, the task of improving a cogeneration plant based on a gas turbine with a waste boiler for the combined production of heat and electricity in communal heating enterprises is set by introducing additional devices into the installation scheme in order to increase the efficiency of the cogeneration plant related to the seasonality of heat supply.

The task is solved by the fact that the installation for the combined production of thermal and electrical energy, which contains a compressor, a combustion chamber, a gas turbine with an electric generator, a recovery boiler,

installed after the gas turbine, a system of pipelines and gas ducts, heating equipment, an automation and regulation system, according to the utility model, the installation additionally contains a regenerator connected by an additional gas duct with a gas turbine and an air duct with a combustion chamber, a gas-water heat exchanger for hot water supply, connected additional gas pipes with a regenerator and a waste boiler, a system for regulating the distribution of combustion products, and the compressor, made of water-cooled, is connected by a water pipeline to a heat exchanger for hot water supply.

The regenerator is necessary to increase the efficiency of the gas turbine during the summer period of operation.

A gas-water heat exchanger is necessary to ensure year-round hot water supply. 70 Additional gas ducts with shutters and pipelines are necessary to connect the elements of the installation.

The system for regulating the distribution of combustion products is necessary to regulate the distribution of combustion products between the regenerator and the recovery boiler.

Making the compressor water-cooled is necessary to reduce mechanical energy on its drive and ensure a high degree of regeneration in the summer.

The connection of the compressor cooling system with the gas-water heat exchanger is necessary to use the compressor cooling heat in the hot water supply system.

The essence of the useful model is explained by the drawing, which depicts the schematic diagram of the proposed installation for the combined production of thermal and electrical energy.

The installation includes a gas turbine, which consists of a water-cooled compressor 1 with stages and heat exchangers (the drawing shows a two-stage water-cooled compressor; the number of stages may be greater), a combustion chamber 2, a gas turbine З with an electric generator 4, a regenerator 5, a recovery boiler 6, a gas-water heat exchanger for hot water supply 7, feed pump 8, gas ducts with shutters 9, 10, 11, 12, 13, 14, 15. The drawing also conventionally shows the thermal energy consumer (heating) 16.

The installation works, depending on the season, as follows. In winter, when heat consumption increases, shutters 9, 11, 12, 13 are closed. Shutters 10, 14, 15 remain open.

The high-temperature exhaust gases from the gas turbine C are sent to the recovery boiler 6. Return water from the heat network is supplied to the recovery boiler t by the feed pump 8. The target heat carrier (steam or hot water) is directed to the consumer of heat energy 16 (heating) after the heat recovery boiler. Waste gases that still have sufficient thermal potential after the waste heat exchanger 6 are sent to the gas-water heat exchanger 7 for hot water supply, which is supplied with water from the cooling system of compressor 1. Hot water from the heat exchanger 7 is sent to the hot water supply network (DHW) , and the gases cooled in the heat exchanger are sent to the chimney. co

In the summer, when heat energy needs are limited only to hot water supply, the flow of combustion products from the gas turbine is directed differently. Shutters 10, 14, 15 are closed. Shutters 9, 11, 12, 13 remain open. d)

High-temperature gases from the gas turbine are sent to the regenerator 5, where the compressed air is sent after "- compressor 1. In the regenerator, the compressed air is heated due to the heat of the exhaust gases from the gas turbine, after which the hot air is sent to the combustion chamber 2. In this way, the transformation of the simple cycle of the gas turbine takes place on regenerative. Since the compressor is water-cooled and the temperature of the compressed air supplied to the regenerator is low, the degree of regeneration is limited only by the need for sufficient thermal potential of waste gases from the regenerator to provide hot water supply and is sufficient to ensure the increase in efficiency of the gas turbine. . Waste gases from the regenerator are fed into the gas-water heat exchanger 7 to heat the water coming from the water cooling system of the compressor, after which they are sent to the chimney.

Undoubtedly, cogeneration plants are most effective in winter, when a significant amount of fuel in heat energy is spent on obtaining thermal energy. In the summer, their efficiency drops significantly, which is reflected in the payback period of these installations. But this can be prevented if, in the summer, cogeneration plants are considered as electricity generators with the supply of electricity to the electric

Me, the network. The use of the regeneration cycle in the summer allows you to increase the electrical efficiency of the GTU to 38-42905, which

Go! makes them competitive as basic electricity generating machines compared to existing basic CHP and condensing power plants (ccd 32-35905).

Me. The seasonal operation of the regenerator and waste boiler has little effect on the payback periods of cogeneration

Ф installations, since the main share in investments in cogeneration installations is the cost of gas turbines.

The use of the proposed useful model will contribute to the spread of cogeneration technologies, which today are the most progressive technologies in heat energy.

Sources of information 1. Ryzhkin V.Ya. Thermal and electric stations. M.: "Znergia", 1967. p. 2. Kanaev A.A., Korneev M.I.. Steam and gas installations. L.: "Mashinostroenie", 1974. 3. Stepanov R.Y.. Boilers with pre-activated gas turbines. - Teploznergetika", 1995, Mo4, pp. 41-43. 4. Arsen'ev L.V., Tnirishkin P.G. Combined plants with gas turbines. L.: "Mashinostroenie", in the Leningrad Department, 1982. 5. Catalog O0O "Nalym", Sevastopol, Ukraine 6. Cogeneration plants (for combined production of electrical energy and heat).

Catalog of JSC "Pervomaiskdizelmash", Pervomaisk, Ukraine. 7. WASH mini-thermal power stations. "Avtomotors", General representative office of AS "OBO" 65 (Germany) in Ukraine, Kyiv. 8. GTZS of the cogeneration cycle (thermal heating). Catalog of gas turbine equipment.

"Gas Turbine Technologies", 2005, Russia.

Claims (1)

Formula of the invention Installation for the combined production of thermal and electrical energy, which contains a compressor, a combustion chamber, a gas turbine with an electric generator, a recovery boiler installed after the gas turbine, a system of pipelines and gas ducts, heating equipment, an automation and regulation system, which differs /0 TIM , that the installation additionally contains a regenerator connected by an additional gas pipe with a gas turbine and an air duct with a combustion chamber, a gas-water heat exchanger for hot water supply, connected by additional gas pipes with a regenerator and a recovery boiler, a system for regulating the distribution of combustion products, and a compressor made of water-cooled , connected by a water pipeline to a heat exchanger for hot water supply. that 2 (Se) (Se) (ee) (Se) yo - and? - (o) (ee) (o) 4) 60 b5