DE4030174A1 - EXHAUST SYSTEM FOR A HEATING PLANT, ESPECIALLY A GAS TURBINE PLANT - Google Patents

Abstract

An exhaust system (1) for evacuating hot waste gas from a thermal electric station (2), in particular a gas turbine station, has at least one channel section (3, 4, 5, 6) with a wall (7) made of metal, provided with at least one cooling channel (8), and that can be cooled by a cooling fluid that flows therein. This exhaust system (1) allows cheap materials to be used, possibly with limited thermal resistance. It can be coated with usual anticorrosive paints and allows the otherwise required, expensive thermal insulations to be dispensed with. The exhaust system (1) can be advantageously used to heat an inert substance that is to be supplied to the burner (24) of the thermal electric station (2) in order to influence combustion therein.

Description

The invention relates to an exhaust system for deriving a hot exhaust gas from a thermal power plant, in particular from a gas turbine system, as well as one with such an exhaust gas system-provided thermal power plant.

Exhaust systems for thermal power plants, especially gas turbines were in DE 27 33 931 A1 and EP 00 87 643 B1 described. EP 00 87 643 B1 relates to a multi-part Exhaust duct as an exhaust system for a gas turbine with one Outflow housing, which is directly connected to the gas turbine is a downstream exhaust gas deflector, which is horizontal the gas turbine deflects exhaust gas flowing in the vertical direction and designed as a diffuser for slowing the exhaust gas flow is, as well as an exhaust gas chimney through which the exhaust gas is released into the environment is fired. In the exhaust duct, in the direction of flow seen behind the diffuser, there is a silencer to reduce those occurring during operation of the gas turbine Sounds. DE 27 33 931 A1 also proposes to provide the exhaust system with heat exchanger tubes, which can be flowed around by the hot exhaust gas and in which a Fluid, namely water, for the generation of water vapor or Hot water for a steam power plant or a district heating supplier system is heatable. Proposals for the generation of heat in thermal power plants can be found in WO 89/08 803 A1.

The resilience of the materials that make up an exhaust system of a thermal power plant are high requirements deliver. The exhaust gas flowing through the exhaust system has Temperatures in the range between about 500 ° C and 600 ° C and thus leads to considerable heat loads. Accordingly come as materials so far only both corrosion-resistant and stainless steels with high thermal resistance are also possible. Corrosion  Protective coats cannot be applied as these do not withstand the thermal loads that occur. In addition, the components of the exhaust system require a and sound insulation, so that the load-bearing metalli the component's full exhaust temperature accept.

Accordingly, an exhaust gas is intended with the present invention system for a thermal power plant to be created at given load capacity by hot exhaust gas the use allows cheaper and easily processable materials and in addition with anti-corrosion paints u. Like. ver can be seen.

According to the invention, an exhaust system for deriving a hot one Exhaust gas from a thermal power plant, for example a gas Turbine system specified that at least one channel section with a wall made of a metal, which with provided at least one cooling channel and by means of a this guided cooling fluid can be cooled.

According to the exhaust system of a thermal power plant coolable, so on the one hand inexpensive and less thermally resilient materials can be used and others Elaborate heat insulation can be dispensed with. The warmth amount to be discharged from the exhaust system by the cooling system is is not excessively high; the cooling capacity to be used is usually not more than about 10% of the nominal power the thermal power plant. A cooled exhaust system is corresponding also not suitable for the waste heat of a thermal power plant a considerable extent for the district heating supply or the like make usable. However, the cooling system of the Exhaust system as an energy source for auxiliary facilities of the Thermal power plant can be used. For example, it is from the WO 89/08 803 A1 discloses the combustion of fuel in the Combustion chambers of gas turbine systems through the injection of Affect water or water vapor; for example  the combustion temperature to avoid nitrogen oxide education be reduced. For such purposes you can use advantage of the cooling system of the exhaust system as a steam generator be used.

It is also conceivable to use a combined gas and steam turbine power plant to that in the exhaust system of the gas turbine required heat exchangers a cooled exhaust gas Provide fireplace, the cooling system is an assembly of heat is exchanger. So the gas turbine system can start with Exhaust system to be built and operated. The steam power plant can be built at a later time and with the gas turbines system can be combined. The components of the Exhaust system between gas turbine and heat exchanger can be cooled be formed according to the invention; because the cooling capacity such components is not too high, the heat build-up shear practically not affected, but it will be a practical table heat source for the power plant and a Danger zone removed.

As part of a further development of the exhaust gas according to the invention systems, the cooling channel is like a screw around the cooling duct section of the exhaust system.

This can conveniently be done in such a way that on the wall the channel section be a metal tube in a suitable manner consolidates, especially brazed or welded. Another way to form the cooling system is Formation of the channel section with an inner pipe section, through the interior of which the exhaust gas is to be passed, and one the inner tube piece forming a more or less Narrow space surrounding the outer tube piece, the Cooling channel is formed in the space. Possibly. can in the Gap by inserting partitions between interior Pipe section and outer pipe section divided several cooling channels will. In addition, channels can run to form cooling channels shaped half-tubes soldered to the wall of the channel section or welded, cooling channels can also be directly in of the wall, made of pipes and plates,  or from pipes with plate-shaped approaches, together is welded. Of course, cooling channels can ver of various types can be formed and used side by side.

Especially when a coolable channel section with a If a plurality of cooling channels is provided, this is advantageous fortunately with a distribution chamber and a collection chamber provided, each cooling channel with both the distribution chamber as well as communicates with the collection chamber and the cooling fluid deliver a single line to the distribution chamber bar and can be removed from the collection chamber. This makes it easy Connection options for the cooling fluid created. The coolable Channel section of an exhaust system according to the invention can be any mentioned component of the exhaust system. Is particularly important the possibility of cooling the flue gas chimney of the thermal power plant.

The further explanation of the invention is based on the in the drawing shown embodiments. It shows

Figure 1 shows a thermal power plant provided with an exhaust system according to the invention in a schematic representation.

Fig. 2 and 3 special embodiments of a coolable channel portion for an exhaust system according to. The invention.

Fig. 1 shows a thermal power plant 2 , especially a gas turbine plant, which is provided with an exhaust system 1 , which consists of a connected to the thermal power plant 2 to connection piece 4 , an exhaust gas deflector 5 and an exhaust stack 6 . The connector 4 is designed as a diffuser for slowing down the flowing exhaust gas; if necessary, an exhaust system 1 according to the invention can also be equipped with a special diffuser or with other components which act as diffusers. The exhaust stack 6 is equipped with a cooling device according to the invention, recognizable by an annular distribution chamber 14 in the upper region of the exhaust stack 6 and a likewise annular collecting chamber 15 in the lower region of the exhaust stack 6 . Extending between the distribution chamber 14 and the collection chamber 15 to the exhaust chimney 6 around a plurality of cooling channels 8 for a cooling fluid, which can be discharged to the waste gas stack 6 by the flowing exhaust gas heat transferred. The delivery of the cooling fluid to the distribution chamber 14 takes place from a cooling fluid reservoir 16 via a cooling fluid supply line 17 , with a supply line regulator 18 for regulating the flow. In the collection chamber 15 collected, heated cooling fluid is discharged through a cooling fluid discharge nineteenth The entire system for guiding the cooling fluid can be completely or partially open and also closed. Cooling fluid, which is returned to the cooling fluid reservoir 16 , must, however, be cooled beforehand by means of appropriate cooling devices. In the present case, an open cooling fluid system is shown, a branch line branching off from the cooling fluid discharge line 19 , specifically an inert material line 21 for supplying part of the cooling fluid heated in the exhaust gas stack 6 to the thermal power plant 2 . Location for the metering of the supplied cooling fluid Wärmekraftan 2 portion is provided, the cooling fluid discharge pipe 19 after the branch of the Inertstoffleitung 21 with a derivative controller 20th Likewise, the inert material line 21 has an inert substance regulator 22 . When operating the system, the regulator, namely supply regulator 18 , derivative regulator 20 and inert substance regulator 22 , must be coordinated with one another, which is easy to achieve with conventional automatic or semi-automatic control systems. The thermal power plant 2 is a gas turbine plant in the present case, the essential components of which are a compressor 23 for the air required for combustion, a burner system 24 together with the combustion chamber 25 and a turbine 26 . In the burner system 24 , the air coming from the compressor 23 is fed to the combustion chamber 25 , and the gases heated in the combustion chamber 25 are directed to the turbine 26 . The fuel, usually natural gas or heating oil, is fed from a fuel reservoir 27 to the combustion chamber 25 through a fuel line 28 via a fuel regulator 29 . In addition, the combustion chamber 25 is seen with devices for supplying an inert substance, which in the present case is the heated cooling fluid. One of these directions, the heated cooling fluid is supplied via the aforementioned inert line 21 .

Fig. 2 shows a design option for a coolable channel section 3 for use in an inventive exhaust system. The channel section 3 is formed by a tube piece, on the inner wall 7 of which a cooling channel 8 is applied in the form of a helically wound tube, in particular which is brazed or welded.

Another design option for a coolable section of an exhaust system is shown in FIG. 3.

The coolable channel section 3 is formed with an inner pipe section 9 , through the inner region 10 of which the hot exhaust gas is led from the thermal power plant. The inner pipe section 9 is surrounded by an outer pipe section 12 , with an intermediate space 11 remaining. In this intermediate space 11 , a plurality of cooling channels 8 are formed by means of intermediate walls 13 , which are arranged between the inner pipe section 9 and the outer pipe section 12 and connect the two pipe sections 9 , 10 to one another. In the example shown, the duct section 3 is straight, as is the cooling duct 8 . However, neither is generally necessary. The shape of the channel section 3 can be adapted practically as desired to the respective spatial requirements, and the cooling channels 8 are also arbitrary and can be designed according to the respective circumstances.

The invention was essentially based on a gas turbine plant explained. However, it is by no means on exhaust systems from Gas turbine plants limited, but can be used in the frame all thermal power plants in which flows of hot exhaust gas occur.

The exhaust system according to the invention for deriving a hot one Exhaust gas from a thermal power plant is characterized by low demands on the materials to be used and makes otherwise necessary costly thermal insulation dispensable.

Claims (14)

1. Exhaust system ( 1 ) for discharging a hot exhaust gas from a thermal power plant ( 2 ), in particular from a gas turbine system, with at least one channel section ( 3 , 4 , 5 , 6 ) with a wall ( 7 ) consisting of a metal, the at least one Has cooling channel ( 8 ) and can be cooled by means of a cooling fluid guided through it. 2. Exhaust system ( 1 ) according to claim 1, wherein the cooling duct ( 8 ) is placed like a screw around the duct section ( 3 , 4 , 5 , 6 ). 3. Exhaust system ( 1 ) according to claim 1 or 2, wherein the cooling channel ( 8 ) consists of a metal tube which is attached to the wall ( 7 ), in particular soldered or welded. 4. Exhaust system ( 1 ) according to claim 1 or 2, wherein the cooling channel ( 8 ) is formed from a trough-shaped half pipe which is sealingly attached to the wall ( 7 ), in particular soldered or welded on. 5. Exhaust system ( 1 ) according to claim 1 or 2, wherein the cooling channel ( 8 ) in the wall ( 7 ). 6. Exhaust system ( 1 ) according to claim 1 or 2, wherein

• a) the channel section ( 3 , 4 , 5 , 6 ) is formed with an inner pipe section ( 9 ) with an inner region ( 10 ) for guiding the exhaust gas and an inner pipe section ( 9 ) forming an intermediate space ( 11 ) surrounding the outer pipe section ( 12 );
• b) the cooling channel ( 8 ) is formed in the intermediate space ( 11 ).

7. Exhaust system ( 1 ) according to claim 6, wherein in the intermediate space ( 11 ) through several intermediate walls ( 13 ) a plurality of cooling channels ( 8 ) are divided. 8. Exhaust system ( 1 ) according to one of the preceding claims, wherein

• a) a channel section ( 3 , 4 , 5 , 6 ) has a plurality of cooling channels ( 8 ) and a distribution chamber ( 14 ) and a collecting chamber ( 15 );
• b) each cooling channel ( 8 ) communicates with both the distribution chamber ( 14 ) and the collection chamber ( 15 );
• c) the cooling fluid can be delivered to the distribution chamber ( 14 ) and can be removed from the collecting chamber ( 15 ).

9. Exhaust system ( 1 ) according to one of the preceding claims, wherein a channel section ( 3 , 4 , 5 , 6 ) is given by at least one of the following components

• a) a thermal power plant connector ( 4 ),
• b) an exhaust gas deflector ( 5 ),
• c) an exhaust gas diffuser,
• d) an exhaust gas fireplace ( 6 ).

10. Exhaust system ( 1 ) according to one of the preceding claims, wherein by means of the cooling fluid between about 5 ° and about 10% of the available thermal energy can be extracted from about 300 ° C and about 600 ° C hot exhaust gas. 11. Exhaust system ( 1 ) according to one of the preceding claims, wherein water and / or water vapor can be used as the cooling fluid. 12. Exhaust system ( 1 ) according to claim 11, wherein a channel section ( 3 , 4 , 5 , 6 ) has at least one cooling channel ( 8 ) in which water can be evaporated to water vapor. 13. Use of an exhaust system ( 1 ) according to one of the preceding claims for the production of a thermal power plant ( 2 ), esp. A gas turbine system. 14. Use of an exhaust system ( 1 ) according to claim 11 or 12 for the production of a thermal power plant ( 2 ), esp. A gas turbine system, the

• a) has at least one burner system ( 24 ) for the combustion of a fuel in air, which is provided with devices for the provision of water or water vapor;
• b) has at least one inert material line ( 21 ) which connects the cooling channel ( 8 ) of the exhaust system ( 1 ) to the devices for delivering water or water vapor.