RU105945U1 - STEAM-GAS ADJUSTMENT TO A GAS-TURBINE POWER PLANT - Google Patents

Abstract

 1. Combined-gas superstructure to a gas turbine power plant, characterized in that it contains at least two energy modules, each of which includes a waste heat boiler with at least one separate gas burner, configured to communicate with the associated petroleum gas supply channel and with the outlet channel of the gas turbine of the gas turbine power plant, and a steam turbine, which is mechanically connected to the electric generator and simultaneously communicated with the outputs of the recovery boilers of both energy x units, wherein the gas feed channels in steam turbines are interconnected through an adjustable valve. ! 2. Combined-gas superstructure to a gas turbine power plant, characterized in that it contains at least two energy modules, each of which includes a waste heat boiler with at least one separate gas burner, configured to communicate with the associated petroleum gas supply channel and with a separate channel for supplying fuel that has not burned in a gas turbine of a gas turbine power plant, and a steam turbine that is mechanically connected to an electric generator and simultaneously connected with the exits of the boilers tilizatorov both energy modules, while the channels for supplying gas to steam turbines communicated with each other and with the cavity of the chimney.

Description

The utility model relates to heat and power industry and can be used to reconstruct existing gas turbine power plants in order to increase their efficiency, electric power and heat generation.

A device is known for a cogeneration unit designed to simultaneously generate electricity and heat, including an internal combustion engine with an electric generator on one shaft, a fuel supply line, an engine cooling circuit, a heating circuit (heat supply system with heat consumers), a heat exchanger system that transfers heat to the cooling engine fluid and high-temperature exhaust gases to the heating circuit, and the control panel ("Construction Review" // Quality Journal //, St. Petersburg. , N 5 (32), May-June 1999, pp. 16-17). However, this device has insufficient efficiency at a sufficiently high fuel consumption.

In this regard, there are projects to create small power plants of the type of thermal power station, which would guarantee guaranteed supply of small areas with electric energy, the connection of which to the centralized energy distribution system is not economically feasible.

Oil production is always accompanied by associated petroleum gas (APG). Currently, most of the associated gas is flared by oil companies. This situation is due to the fact that the cost of transporting gas to gas collection networks and its technological preparation for transmission to the gas transmission network exceeds the price that oil companies can receive from the sale of this gas at the entrance to the centralized gas transportation network, i.e. APG collection is unprofitable for oil companies. At the same time, flaring of APG causes significant environmental damage to the environment, in connection with which the state constantly raises penalties for oil companies that flare APG.

The idea of utilizing associated petroleum gas (APG) through the construction of energy generating plants is already working everywhere in Russia. At the same time, one of the main directions is the construction of gas turbine power plants (GTES) based on adapted aircraft engines, or specially designed gas turbines that drive electric generators. The efficiency of gas turbine power plants is up to 27-29%. Exhaust gases at the exit of gas turbines have a temperature of 350 to 500 ° C or more, and also include incompletely burned fuel and oxygen. Since APG for oil companies is a by-product and does not “cost” money, they do not complicate GTES with additional technological add-ons that can increase their efficiency.

Also known are power plants using a combined cycle cycle, or cogeneration in the generation of electrical and, if necessary, thermal energy - combined cycle power plants (CHPPs). In the combined heat and power plant, high-temperature exhaust gases from gas turbines are used to produce steam in waste heat boilers, and steam, in turn, drives the steam turbines that are connected to the generators. The use of such a scheme makes it possible to increase the efficiency of the cogeneration plant up to 50%.

Gas turbines have a short overhaul period, which leads to their frequent conclusion in repair and routine maintenance. At the same time, the combined cycle cogeneration plants of the standard scheme lose power in generating electricity both from gas generation from the output of the gas turbine and from steam generation from a decrease in the amount of heat entering the recovery boiler from the exhaust of the turbines. In addition to this, for the period of the gas turbine withdrawal, again there is a need to burn excess APG in the flare.

For example, a combined cycle gas power plant is known, which is characterized by the fact that it includes two power modules, each of which contains a gas turbine communicated with a channel for supplying associated petroleum gas, mechanically connected to an electric generator, a waste heat boiler with a separate gas burner, and communication with a supply channel associated petroleum gas and with a separate channel for supplying exhaust gases and unburned fuel in a gas turbine, as well as a steam turbine that is mechanically connected to an electric generator at the same time communicated with the outputs of the recovery boilers of both energy modules, while the energy modules are communicated with a common channel for supplying associated petroleum gas, and the channels for supplying steam to steam turbines are communicated to each other through an adjustable valve (RU No. 87503, F25B 29/00, publ 10.10.2009). The decision was made as a prototype for the declared objects.

The disadvantage of this power plant is that it is a stationary mounted station, which is an integral part of the energy complex, the parameters of which are laid at the stage of preparation of the technical project. At the same time, such power plants operate in realities that are not equipped with recovery boilers, associated petroleum gas is supplied to the gas turbine and utilized. Utilization of heat from the exhaust gases of gas turbines and afterburning of unburned APG contained in them in a waste heat boiler can increase the efficiency of electricity generation, as well as additionally obtain thermal energy.

This utility model is aimed at achieving a technical result, which consists in improving operational characteristics and increasing efficiency in terms of utilization of associated petroleum gas and afterburning of untreated gas fuel in gas turbines.

The specified technical result for the first embodiment is achieved by the fact that the combined-cycle superstructure to the gas turbine power plant contains at least two energy modules, each of which includes a recovery boiler with at least one separate gas separate gas burner, configured to communicate with a channel for supplying associated petroleum gas and with an exhaust channel of a gas turbine of a gas turbine power plant, and a steam turbine that is mechanically connected to an electric generator and simultaneously communicated with the exits of the recovery boilers of both energy modules, while the channels for supplying gas to steam turbines are communicated to each other through an adjustable valve.

The specified technical result for the second embodiment is achieved by the fact that the combined-cycle superstructure to the gas turbine power plant contains at least two energy modules, each of which includes a recovery boiler with at least one separate gas separate gas burner, configured to communicate with a channel for supplying associated petroleum gas and with a separate channel for supplying fuel unburnt in a gas turbine of a gas turbine power plant, and a steam turbine that is mechanically connected to an electric generator and communicates simultaneously with the outputs of the two waste heat boilers of power modules, wherein the gas feed channels in steam turbines are interconnected with a cavity and a chimney. These features are significant and are interconnected with the formation of a stable set of essential features sufficient to obtain the desired technical result.

The present utility model is illustrated by a specific example of execution, which, however, is not the only possible one, but clearly demonstrates the possibility of achieving the required technical result.

Figure 1 - block diagram of a combined-cycle superstructure according to the first embodiment;

figure 2 is a block diagram of a combined-cycle superstructure according to the second embodiment.

According to this utility model, the design of a gas-vapor superstructure is considered, which can be used as an addition to existing and operating gas turbine power plants, which will ensure 100% utilization of associated gas under all conditions of combined cycle power plants, as well as minimize losses in the generation of electric and thermal energy when gas turbines are brought to repairs and routine maintenance. The essence of the utility model is that it is proposed to put a gas-vapor superstructure to an existing gas-turbine power plant by taking the turbine exhaust into an active waste-heat boiler with burners, and by supplying gas to the waste-heat boiler to burn unburned fuel and to operate the boiler autonomously when gas turbines are being exhausted. in repairs and maintenance. The proposed combined heat and power plant includes active waste heat boilers that use not only the heat from the exhaust of gas turbines, but also have their own gas burners. In normal mode, in parallel operation of the gas turbine + recovery boiler + steam turbine, the burner is additionally supplied with fuel to the recovery boiler, which allows you to burn fuel that has not burned in the gas turbine and raise the steam temperature, which increases the steam output of the recovery boiler and allows you to set a more powerful steam turbine. When a gas turbine is put out for repair or for a regulation, the resulting excess fuel (APG) is fed to the burners of the recovery boiler, which ensures the steam parameters of the boiler as in normal operation. Thus, for the combined heat and power plant performed according to the indicated scheme, losses in electric power generation are reduced only by the power of the gas turbine taken out of operation, and electric power generation by a steam turbine and thermal energy are saved in full. There is also no need to burn excess APG in a flare, which, under the proposed scheme, is fully utilized at all plant operating modes, including when putting gas turbines into service.

The combined-cycle superstructure (Fig. 1) to the gas turbine power plant according to the first embodiment contains at least two energy modules, each of which includes a waste heat boiler with at least one separate gas burner, configured to communicate with the associated feed channel oil gas and with the exhaust channel of a gas turbine of a gas turbine power plant, and a steam turbine that is mechanically connected to an electric generator and at the same time connected to the outputs of the recovery boilers of both energy modules, while the channels for supplying gas to steam turbines are interconnected via an adjustable valve.

The combined-cycle superstructure (FIG. 2) to the gas turbine power plant according to the second embodiment contains at least two energy modules, each of which includes a recovery boiler with at least one separate gas burner, configured to communicate with the associated petroleum feed channel gas and with a separate channel for supplying fuel that has not burned in a gas turbine of a gas turbine power plant, and a steam turbine that is mechanically connected to an electric generator and simultaneously connected with outputs to catching and utilizing both energy modules, while the channels for supplying gas to steam turbines are interconnected with each other and with the chimney cavity.

Combined-cycle power plant in combination with a combined-cycle superstructure (Fig. 1) contains a gas turbine 2 mechanically connected to the associated petroleum gas supply channel 2 and mechanically connected to an electric generator 3, a waste heat boiler 4 with at least one separate gas gas burner communicated with a channel 1 for supplying associated petroleum gas and with a separate channel 5 for supplying unburned fuel in a gas turbine to a chimney and with a steam turbine 6, which is mechanically connected to an electric generator 7, and the gas turbine It can be disconnected from the channel for supplying associated petroleum gas. This design can be a separate energy module 8. The chimney is indicated by pos.9. A combined cycle gas turbine power plant can be composed of two energy modules 8 and 10, each of which contains a gas turbine mechanically connected to the associated petroleum gas supply channel, connected to an electric generator, a waste heat boiler with a separate gas burner, connected to the associated petroleum gas supply channel, and with a separate feed channel for unburned fuel in a gas turbine. For such modules, one steam turbine 6 can be used, which is mechanically connected to an electric generator 7 and simultaneously connected with the outputs of 11 recovery boilers 4 of both energy modules, while the energy modules are communicated with a common channel 1 for supplying associated petroleum gas, and gas supply channels steam turbines are interconnected through an adjustable valve 12.

In this combined cycle power plant, a combined-cycle superstructure is used (Fig. 1) (first embodiment), which as a separate unit contains at least two energy modules, each of which includes a recovery boiler with a separate gas burner, configured to communicate with a channel for supplying associated petroleum gas and is additionally configured to communicate with a chimney cavity for utilization of a gas fuel unburned in a gas turbine of a gas turbine power plant, and steam a turbine which is mechanically connected to an electric generator and communicates simultaneously with the outputs of the two waste heat boilers of power modules, wherein the gas feed channels in steam turbines are interconnected through an adjustable valve.

In the combined cycle power plant, a combined-cycle superstructure (Fig. 2) (second embodiment) can be used, which contains at least two energy modules, each of which includes a recovery boiler with at least one separate gas separate gas burner, made with the possibility of communication with a channel for supplying associated petroleum gas and with a separate channel for supplying fuel unburnt in a gas turbine of a nasoturbine power plant, and a steam turbine that is mechanically connected to an electric generator of and simultaneously communicates with the outlets of the two waste heat boilers of power modules, wherein the gas feed channels in steam turbines are interconnected with a cavity and a chimney.

This utility model is industrially applicable, can be implemented using technologies used in the manufacture of gas turbine units and systems for the formation of hot gas flows.

Claims (2)

1. Combined-gas superstructure to a gas turbine power plant, characterized in that it contains at least two energy modules, each of which includes a waste heat boiler with at least one separate gas burner, configured to communicate with the associated petroleum gas supply channel and with the outlet channel of the gas turbine of the gas turbine power plant, and a steam turbine, which is mechanically connected to the electric generator and simultaneously communicated with the outputs of the recovery boilers of both energy x units, wherein the gas feed channels in steam turbines are interconnected through an adjustable valve. 2. Combined-gas superstructure to a gas turbine power plant, characterized in that it contains at least two energy modules, each of which includes a recovery boiler, with at least one separate gas burner, configured to communicate with the associated petroleum gas supply channel and with a separate channel for supplying fuel that has not burned in a gas turbine of a gas turbine power plant, and a steam turbine that is mechanically connected to an electric generator and simultaneously connected with the exits of the boilers tilizatorov both energy modules, while the channels for supplying gas to steam turbines communicated with each other and with the cavity of the chimney.