DE19630058A1 - Seasonally configured combined cycle thermal power station for remote heat supply system - Google Patents

Abstract

The power plant (30) contains a gas turbine unit (32) for generating electric power and hot exhaust fumes, and a water heating arrangement (36) for a recovery of the heat of the exhaust fumes. The water heating arrangement contains an indirect heat exchange (56A) for transferring heat from the exhaust fumes to the water in the exchange, whereby hot water is produced. The power plant contains furthermore a hot water usage device (12) which uses the heat in supplied hot water in seasonally changing quantities. An organic cycle converter (50) with an evaporation arrangement (52) receives hot water and produces organic steam. A turbine (54) for organic steam is provided for generating relaxed organic steam and electric power. A capacitor (56) for organic steam is provided for condensing the relaxed organic steam and for generating a condensation. A device (60) is provided for leading back the condensation into the evaporation arrangement.

Description

The present invention relates generally to the Area of seasonally configurable cogeneration plant systems with combined cycle and in particular on one Power plant of this type, the hot water for a hot water utilization device such. B. a district heating system Provides.

In a combined heat and power plant Heat contained in the hot exhaust gases, which generated by a gas turbine driving a generator a heat recovery steam generator (HRSG) fed, which generates steam that a steam turbine is supplied, which generates additional power. This Arrangement can be used when using the power plant a hot water device such. B. a district heating measuring system is equipped. The latter is a system that Low level heat for space heating and / or used light industrial purposes, one meaning aspect of the same a seasonal change is the thermal load used by the system.

In the conventional power plant described above Steam removed from an intermediate stage of the steam turbine and fed to the hot water utilization device. That ver needed cooled water from the hot water use direction is generated together with condensate is generated by a condenser through which the exhaust gas the steam turbine is directed, returned to the HRSG, to close the water cycle.  

In such a conventional arrangement, there are several re problems. First, HRSGs and steam turbines are in primarily due to the pressures used to maximize tion of thermal efficiency is relatively complicated and thus in terms of investment costs and Maintenance relatively expensive. In addition, the system controls gene and operations complicated to a customized and Safe control of the steam turbine in combination with the Ensure hot water use device. The Wasserbe action is decisive for a stationary year-round business. Finally, the necessary controls even more complicated when using hot water device required amount of heat fluctuates seasonally.

It is therefore the object of the present invention new and improved combined heat and power plant creating a cycle that is easier and cheaper to build and operate as Stan power plants of technology.

According to the invention, this object is achieved by a Seasonally configurable combined heat and power plant ned cycle, which the in claims 1, 8 or 9 has the specified characteristics. The dependent claims are directed to preferred embodiments.

Other features and advantages of the present invention will become clear upon reading the following description preferred embodiments referring to the attached Reference to drawings; show it:

Fig. 1 is a schematic block diagram of a combined cycle power plant according to the present invention, which contains a heat recovery water heater, a hot water utilization device and an organic Rankine cycle converter;

Fig. 2 is a schematic block diagram of a conventionally combined heat and power plant with a combined cycle, which shows how heat with a low level of a heat utilization device such. B. a Fernwärmesy system is supplied;

Figs. 3A to Heißwasserströmungsweg during a loading operation mode of the power plant of Figure 1, in which the district heating system has a relatively low heat load demand.

Fig. 3B the Heißwasserströmungsweg during a loading operation mode of the power plant of Figure 1, in which the district heating system has a relatively high heat load demand.

Fig. 4 is a block diagram of a modification of the power plant shown in Fig. 1, showing a liquid-cooled condenser for the organic steam turbine, which serves to preheat the cooling water consumed by the hot water utilization device; and

Fig. 5 is a schematic representation of a central controller for the operation of the valves that make the connections between the heat recovery water heater, the hot water device and the organic Rankine cycle converter.

In Fig. 2, reference numeral 10 designates a conventional combined heat and power plant, in which hot water is supplied to a heat utilization device in the form of a district heating system 12 . A gas turbine unit 14 generates hot exhaust gases while the turbine drives a generator that generates electrical power. The heat contained in these gases is transferred to the water contained in the heat recovery steam generator 16 , thereby generating steam which is expanded in the steam door 18 to generate electrical power, whereupon the relaxed steam is condensed in the condenser 20 . The condensate generated by this condenser is returned from a circuit pump to the steam generator 16 .

From an intermediate stage 22 of the turbine 18 , steam is drawn off at a low level and passed through a pressure reduction valve 23 before it is converted to hot water, which is passed to the system 12 . The used, cooled water generated by the system 12 is returned to the steam generator 16 via a water treatment unit 24 .

As shown in FIG. 1, a power plant 30 according to the present invention includes a gas turbine unit 32 for generating electrical power in the generator 33 and hot exhaust gases in the exhaust pipe 34 . The exhaust gases are discharged via a heat recovery water heating device 36 to the atmosphere, wherein said heat recovery water heater 36 of an indirect heat exchanger in the form of multiple sets of windings 36 A, 36 B has, with which the flowing heat between the exhaust gases and by the turns Water is exchanged so that hot water emerges at the outlet 38 . A hot water use device in the form of a district heating system 12 receives the hot water, which is supplied via an inlet line 40 . The system 12 uses the heat in the hot water in the line 40 in seasonal fluctuating amounts and generates used, cooled water which is returned to the heating device 36 via a line 42 .

The used water enters the inlet 43 of the upper turn 36 A next to the top of the stack which forms the jacket of the heater 36 , and exits from this turn at the outlet 44 , which is connected via the valve A to the line 40 and the valve B is connected to the inlet 45 of the lower winding 36 B. The line 42 , which carries the used water, is also connected via the valve C to the inlet 45 , with the result that the used water from the system 12 is fed in parallel to the turns 36 A and 36 B when the valve C is open . When valve B is open and valve A is closed ( Fig. 3A), part of the consumed water runs through turn 36 A and is heated, but all of the used water runs through turn 36 B and is further heated.

The outlet 38 of the turn 36 B is connected to the line 40 via the valve D. When the valves A, C and D are closed and the valve B is open (Fig. 3B), flows a part of the water consumed by the Win 36 A dung and the rest through the winding 36 B.

The organic Rankine cycle converter 50 is connected to the outlet 38 via the valve E. The converter 50 includes an evaporator 52 , which is an organic fluid such. B. contains isopentane and receives the hot water supplied via the valve E to generate organic steam. The organic steam turbine 54 relaxes the organic steam and generates expanded organic steam, which is supplied to the organic steam condenser 56 , and drives the generator 58 , which generates electrical power.

The condenser 56 condenses the expanded organic vapor released by the turbine 54 and generates condensate, with the circuit pump 60 returning the condensate to the evaporator to complete the organic fluid circuit. If the condenser 56 is arranged sufficiently elevated relative to the evaporator, the circulation pump can be omitted.

The valves A, B, C, D and E form optionally adjustable valves which connect the heat recovery water heating device 36 to the hot water utilization device 12 and to the converter 50 in order to supply the distribution of the evaporator 52 to the converter 12 and the hot water usage device 12 hot water to regulate optionally. More specifically, when the heat load of the hot water device is low, e.g. B. during the summer, the electrical power generated by the converter 50 is maximized. In such a case, the states of the valves are as follows:

State 0 means that the valve is closed (ie no flow is permitted), while state 1 means that the valve is open (ie flow is permitted).

If the heat load of the hot water utilization device is high, e.g. B. during the winter, the electrical power generated by the converter 50 is maximized. In such a case, the states of the valves are as follows:

With this arrangement, in which only two states (ie, open / closed or on / off) are allowed for the valves, the generator 58 provides 100% power during the summer, while it provides no power during the winter. In this arrangement, the valves and associated controls are constructed and arranged such that all of the water supplied to the hot water utilization device either bypasses the converter and is passed directly into the device or flows through the converter before it is supplied to the device.

Although the valves can be operated manually, they are preferably operated electrically or pneumatically by a central controller, as shown in FIG. 5. In such a case, the central controller, in conjunction with the valves, forms a device for supplying hot water from the indirect heat exchanger in the heat recovery water heater either directly to the hot water utilization device, bypassing the evaporator of the converter, or serially through the evaporator to the hot water utilization device .

However, the present invention also uses an arrangement in which the valves can assume other states (ie, partially open). In such a case, the valve E can be partially opened in order to cause a partial flow into the evaporator 52 of the converter 50 .

Because of its simplicity, an air-cooled condenser is preferred for converter 50 . However, where circumstances allow, the organic vapor condenser can be cooled by a liquid coolant. This is shown in Fig. 4, which shows a converter 50 A, which is similar to the converter 50 . The converter 50 A includes an evaporator 52 which supplies organic steam to the organic steam turbine 54 which drives the generator 58 and generates relaxed organic steam which is fed to the indirect heat exchanger 56 A which serves as a condenser for the turbine 54 . A liquid coolant such as B. On-site water, which is supplied to the heat exchanger 56 A, is heated by the condensation of the relaxed organic steam, the heated coolant being supplied to the preheater 66 , which preheats the used water generated by the district heating system 12 before the used water is used Heat recovery water heater 36 is recycled.

The benefits and improved results from that Method and device of the present invention can be achieved from the previous description exercise of the preferred embodiment of the invention Lich. There can be various changes and modifications be made without the spirit and scope of Invention as be in the appended claims is written to deviate.

Claims (9)

1. Seasonally configurable combined heat and power plant ( 30 ) with a gas turbine unit ( 32 ) for generating electrical power and hot exhaust gases, characterized by

• (A) a heat recovery water heater ( 36 ) which receives the exhaust gases and contains an indirect heat exchanger ( 36 A, 36 B) to transfer the heat in the exhaust gases to the water in the heat exchanger ( 36 A, 36 B) and hot To produce water;
• (b) a hot water utilization device ( 12 ) which receives its supplied hot water in order to use the heat in the hot water in a seasonally fluctuating amount;
• (c) an organic Rankine cycle converter ( 50 ), with an evaporator ( 52 ) that receives the hot water supplied to it to generate organic steam, an organic steam turbine ( 54 ) to relax the organic steam and generate relaxed organic steam and electrical power, an organic steam condenser ( 56 ) for condensing the expanded organic steam and generating condensate, and a device ( 60 ) for returning the condensate to the evaporator ( 52 ); and
• (d) optionally adjustable valves (A, B, C, D, E) which connect the heat recovery water heater ( 36 ) with the hot water utilization device ( 12 ) and the converter ( 50 ) to the distribution of the evaporator ( 52 ) of the Optionally regulate the converter ( 50 ) and the hot water supply to the hot water utilization device ( 12 ).

2. Power plant according to claim 1, characterized in that the valves (A, B, C, D, E) are constructed and arranged so that all of the hot water utilization device ( 12 ) supplied water either bypasses the converter ( 50 ) and directly Device ( 60 ) is fed or flows through the converter ( 50 ) before it is fed to the device ( 60 ). 3. Power plant according to claim 1, characterized in that the condenser ( 56 ) is air-cooled for organic steam. 4. Power plant according to claim 1, characterized in that the condenser ( 56 ) for organic steam is cooled with a liquid coolant. 5. Power plant according to claim 1, characterized in that the condenser ( 56 ) for organic steam is cooled with a liquid coolant, whereby heated coolant is generated, and the hot water utilization device ( 12 ) generates used cooled water, which for the heat recovery water heating device ( 36 ) is recycled and includes a preheater ( 66 ) that receives the heated coolant to preheat the used water before returning it to the heat recovery water heater ( 36 ). 6. Power plant according to claim 1, characterized in that the indirect heat exchanger ( 56 A) contains several separate turns. 7. Power plant according to claim 1, characterized by a device for optional adjustment of the Valves (A, B, C, D, E) from a central location. 8. combined cycle power plant ( 30 ) with a gas turbine unit ( 32 ) for generating electrical power and hot exhaust gases, characterized by

• (a) a heat recovery water heater ( 36 ) for receiving the exhaust gases, which includes an indirect heat exchanger ( 56 A) to transfer the heat in the exhaust gases to the water in the heat exchanger ( 56 A) and produce hot water;
• (b) a hot water utilization device ( 12 ) which receives its supplied hot water and uses the heat in the hot water and generates used, cooled water which is returned to the heat recovery water heater ( 36 );
• (c) an organic Rankine cycle converter ( 50 ) having an evaporator ( 52 ) that receives the hot water supplied to it to produce organic steam, an organic steam turbine ( 54 ) to relax the organic steam and produce relaxed organic steam Steam and electrical power, an organic steam condenser ( 56 ) for condensing the expanded organic steam and generating condensate, and a device ( 60 ) for returning the condensate to the evaporator ( 52 ); and
• (d) a device (A, B, C, D, E) for supplying hot water from the indirect heat exchanger ( 56 A) either directly to the hot water utilization device ( 12 ), bypassing the evaporator ( 52 ) of the converter ( 50 ) , or in series via the evaporator ( 52 ) to the hot water utilization device ( 12 ).

9. Combined cycle thermal power station ( 30 ), with a gas turbine unit ( 32 ) for generating electrical power and hot exhaust gases, a heat recovery water heater ( 36 ) which receives the exhaust gases and contains an indirect heat exchanger ( 56 A) to the heat to transfer in the exhaust gases to the water in the heat exchanger ( 56 A) and to produce hot water, a hot water utilization device ( 12 ) which receives the water from the heat exchanger ( 56 A) and generates used cooled water, characterized by

• (a) an organic Rankine cycle converter ( 50 ) with an evaporator ( 52 ) which receives the hot water supplied to it and generates organic steam, a turbine ( 54 ) for organic steam which relaxes the organic steam and relaxed organic steam and electrical Generating power, and an organic vapor condenser ( 56 ) for condensing the expanded organic vapor and generating condensate, and a device ( 60 ) for returning the condensate to the evaporator ( 52 ); and
• (b) a device (A, B, C, D, E) for selectively turning on the converter between the hot water utilization device ( 12 ) and the heat recovery water heater ( 36 ).