DE4329585A1 - Gas turbine heating/refrigerating unit-type power station - Google Patents

Abstract

The invention relates to a gas turbine heating/refrigerating unit-type power station for realising a total energy assembly. As a matter of priority, the cold is generated by a cold air refrigerating machine which is driven by the exhaust gas of an open gas turbine plant which is fitted with a thermal regenerator. By comparison with unit-type heating/refrigerating power stations having gas engines or diesel engines, in the gas turbine plant the entire exhaust gas mass flow is available for driving the cold air refrigerating machine. Consequently, with regard to the very low overall volume, the low overall mass and the environmentally friendliest coolant i.e. air, the machine has the advantage of being used to generate cold in a total energy assembly which is not connected to high-power heat engines. This means that it can also be very advantageously used in particular in mobile unit-type heating/refrigerating power stations such as, eg, on ships.

Description

The invention relates to one with cold air cooling machine and heat exchanger coupled open gas Binenanlage, so that electrical, heating and Cold energy can be generated.

It is known that according to the prior art Heat engines (diesel and gas engines, gas turbines plants) in addition to mechanical or electrical energy Use of the through the engine cooling and / or with the Exhaust gas energy at the same time heating and Refrigeration energy is generated, making a so-called total energy network is realized.

According to the proposal in P 41 06 046.6, surplus is used according to the exhaust gas of a supercharged internal combustion engine Cold air chiller driven. Throughout the whole Exhaust gas mass flow used to provide heating energy only part of the refrigeration system is available Exhaust gas mass flow available to charge the Motors is not needed. The provision of larger Cooling capacities are therefore great on motors bound.

Furthermore, the state of the art in realizing of a total energy network, characterized in that the heat of the cooling water and the exhaust gas mass flow from Internal combustion engines both for heat energy generation and also for generating cold with absorption chillers is used, however, to the well-known large Bauvolu mina and masses of such systems contribute.  

The aim of the invention is a block-heating-cooling power plant to develop small building volumes and small building dimensions, with which the entire exhaust gas mass flow of the heat engine for the generation of cooling and heating energy to a high degree can be used in an energy-saving and ecological way.

The invention is based on the object light and small heat engine with one also lightweight and small chiller that works with a highly environmentally friendly refrigerant tet, and alternatively also with absorption cooling to couple the machine so that all or just one Part of the exhaust gas mass flow for the generation of heating and Cold energy or also for thermal regeneration of the Heat engine is used so that easily different requirements on the part of heating and Cooling needs of a supply area are reacted to can.

According to the invention this object is achieved in that an open gas turbine plant with a thermal Is equipped with one with the exhaust gas Gas turbine driven cold air and alternatively the same in time with an absorption chiller and with Heat exchangers in which the exhaust gas and those in the air compress the warmed air from the cold air chiller cools and is used to provide heating energy, so is coupled that on the one hand the entire exhaust gas mass flow for generating cooling or heating energy stands, but on the other hand without problems at all times changing needs of these forms of energy can be reacted to can, if the one not needed for these forms of energy Exhaust gas energy to ensure high levels of efficiency too  in the partial load range of the gas turbine heating-cooling block force plants in the regenerator of the gas turbine plant is always optimally exploited.

The invention will be explained below with reference to an embodiment example according to FIG. 1 and FIG. 2.

The open gas turbine plant according to Fig. 1 - consisting of air compressor 1, the regenerator 2, combustion chamber 3, the gas turbine 4, generator 5 and exhaust gas purification system 6 - drives the controllable via the valve 7 exhaust gas mass flow to a cold air cooling machine. This consists of the exhaust gas turbine 8 , two air compressors 9 and 10 , an air cooler 11 , an air turbine 12 and alternatively a heat exchanger 13 with which, after reaching a steady operating state by switching off the outside air supply 14 with the three-way valve 15, a closed cold air process is realized becomes. The exhaust gas relaxation turbine 8 drives the air compressor 9 , with which it is arranged on a shaft. This sucks in outside air 14 or circulating air 16 in the closed process and compresses it to the maximum process pressure of the cold air refrigerator, which heats up. It is cooled back in the air cooler 11 and then expanded to the minimum process pressure in the air expansion turbine 12 , the air being cooled and used in the heat exchanger 13 as an alternative for cooling a cooling brine 17 . The air expansion turbine 12 drives the air compressor 10 with which it is arranged on a shaft. This sucks like the air compressor 9 outside air 14 or in the closed process circulating air 16 , which is compressed by the pressure valve 18 compressed to the maximum process pressure set with the pressure valve 19 and the compressor 9 promoted by the air mass flow until added a steady operating state is reached. In this state, the total air mass flow 16 is cooled down in the cooler 11 , ent in the air expansion turbine 12 and further cooled, so that a desired cooling energy is provided in the heat exchanger 13 by cooling the cooling brine 17 . The exhaust gas mass flow ent tensioned in the exhaust gas turbine 8 is cooled in the exhaust gas heat exchanger 20 by heating a heating energy carrier 21 , whereby part of the heating energy is provided. Additional heating energy can be provided with the air cooler 11 by cooling the compressed air via a heating energy carrier 22 . If no heating energy is required, the exhaust gas mass flow escaping from the exhaust gas turbine 8 by means of the four-way valve 23 bypasses the exhaust gas heat exchanger 20 and is blown off into the open via the regenerator 2 , in which the air compressed in the compressor 1 is preheated, and the exhaust gas cleaning system 6 . As soon as no cooling energy is required, with the valve 7 closed and in the direction of the exhaust gas heat exchanger 20 , the four-way valve 23 opened, the exhaust gas mass flow of the gas turbine 4 can be used completely for heating energy generation. The heating supply is reduced by providing the exhaust gas heat exchanger 20 and thus the regenerator 2 with corresponding proportions of the exhaust gas.

Fig. 2 shows the coupling of a cold air with an absorption refrigerator 26 , which use the exhaust gas of the gas turbine 4 exclusively for cooling. After the pressure potential of the exhaust gas mass flow for driving the air compressor 9 and thus for driving the cold air refrigeration machine has been reduced in the exhaust gas turbine 8 , it is supplied with almost ambient pressure via a three-way valve 25 to the absorption refrigeration machine 26 in order to provide cooling energy by alternatively using a further cooling brine 27 is cooled down. The exhaust gas mass flow of the gas turbine 4 , which is thus cooled in terms of energy, is discharged to the environment via the three-way valve 24 and the exhaust gas purification system 6 .

Reference list

1 air compressor of the gas turbine system
2 regenerator
3 combustion chamber
4 gas turbine
5 generator
6 Emission control system
7 control valve
8 exhaust gas turbine
9 air compressors of the cold air chiller
10 air compressors of the cold air chiller
11 air coolers
12 air relaxation turbine
13 heat exchangers
14 outside air
15 three-way valve
16 circulating air
17 cooling brine (cold air chiller)
18 pressure valve
19 pressure valve
20 exhaust gas heat exchangers
21 heating energy sources (exhaust gas heat exchangers)
22 heating energy sources (air coolers)
23 four-way valve
24 three-way valve
25 three-way valve
26 absorption chiller
27 cooling brine (absorption chiller)

Claims (4)

1. Gas turbine heating-cooling unit, characterized in that an open gas turbine system - consisting of air compressor ( 1 ), regenerator ( 2 ), combustion chamber ( 3 ), gas turbine ( 4 ) and generator ( 5 ) - with a cold air - Chiller - consisting of an exhaust gas turbine ( 8 ), two air compressors ( 9 and 10 ), an air cooler ( 11 ), an air expansion turbine ( 12 ), a heat exchanger ( 13 ) - and an exhaust gas heat exchanger ( 20 ) connected downstream of the exhaust gas turbine ( 8 ) is coupled so that in addition to electrical energy with the generator ( 5 ) with the entire exhaust gas mass flow of the gas turbine ( 4 ) in the downstream of the air expansion turbine ( 12 ) heat exchanger ( 13 ) cooling energy by cooling down a cooling brine ( 17 ) and in the air cooler ( 11 ) the cold air cooling machine and in which the exhaust gas turbine ( 8 ) after connected exhaust gas heat exchanger ( 20 ) heating energy by heating the heating energy carriers ( 21 and 22 ) at the same time be generated. 2. Gas turbine heating-cooling unit according to claim 1, characterized in that the exhaust gas turbine ( 8 ) is followed by an absorption refrigerator ( 26 ) and so cooling energy is additionally generated by cooling a cooling brine ( 27 ) if required. 3. Gas turbine heating-cooling unit according to claim 1 and 2, characterized in that the in the Luftent voltage turbine ( 12 ) cooled air is used directly for cooling or air conditioning and with the absorption chiller ( 26 ) a cooling brine ( 27 ) is cooled . 4. Gas turbine heating-cooling unit according to claim 1 and 2, characterized in that with the valves ( 7 , 23 , 24 and 25 ) the exhaust gas mass flow of the gas turbine ( 4 ) on the exhaust gas turbine ( 8 ), the absorption refrigerator ( 26 ) and divided between the exhaust gas heat exchanger ( 20 ) and regenerator ( 2 ).