WO2014183235A1 - Combined type condensed steam heat exchange system for direct air cooling steam turbine - Google Patents

Abstract

A combined type condensed steam heat exchange system for a direct air cooling steam turbine comprises a condensation heat exchanger A (1), a condensation heat exchanger B (2), a heating network circulating pump (5), a peak cooling tower A (3), a peak cooling tower B (4), a peak cooling water circulating pump A (6) and a peak cooling water circulating pump B (7). Return water of heat network circulating water is pressurized through the heat network circulating pump (5), fed into the condensation heat exchangers (1, 2) to be heated for waste heat recovery and fed into a heat network to be heated continuously to supply heat outwards after required temperature is reached. When functioning as peak cooling equipment, the condensation heat exchangers (1, 2) and the peak cooling towers (3, 4) form a closed cooling water circulating system, and part of exhaust steam is pumped for cooling. Steam supply systems, air pumping systems and drainage systems of the two condensation heat exchangers (1, 2) are arranged in an alternating header pipe mode so that waste heat recovery of single-machine heat supply operation of the two heat exchangers is achieved.

Description

 BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention generally relates to a heat exchange system, and more particularly to a direct air-cooled steam turbine steam heat exchange system.

BACKGROUND OF THE INVENTION Waste heat recovery technology is an energy saving and emission reduction technology. The design of the direct air cooling unit of the large power station has higher back pressure and exhaust steam temperature than the traditional wet cooling unit. Therefore, there is a large back pressure adjustment space, which is beneficial to the recovery and utilization of waste heat. At present, for large air-cooled units of large power plants, the absorption heat pump or the addition of a high back pressure condenser is mainly used for waste heat recovery. Existing direct air-cooling units, whether using absorption heat pumps for waste heat recovery or adding high back pressure condensers for waste heat recovery, are limited to how to effectively use the residual heat of the unit in winter. These waste heat recovery devices are basically used in summer. Being idle, resulting in low device utilization. In addition, the existing waste heat recovery device does not overcome the disadvantages of high back pressure and poor economic performance of the direct air-cooled steam turbine in summer. SUMMARY OF THE INVENTION The present invention provides a direct air-cooled steam turbine composite condensing heat exchange system, which solves the problem of low utilization rate in the existing waste heat recovery device in summer, and solves the problem of high back pressure of the direct air cooling unit in summer. The present invention solves the above technical problems by the following technical solutions: A direct air-cooled steam turbine composite condensing heat exchange system, including A condensing heat exchanger, B condensing heat exchanger, heat network circulating pump, A peak cooling tower, B The peak cooling tower, the A-peak cooling water circulation pump and the B-peak cooling water circulation pump, the exhaust steam exhaust pipe of the A direct air-cooling unit communicates with the inlet port of the A condensing heat exchanger through the first valve, and passes through the heat exchange condensation The second valve, the first three-way and the third valve disposed on the hydrophobic port of the condensation heat exchanger are in communication with the input port of the exhaust device of the direct air-cooling unit of the A; the outlet of the heat network circulation pump is condensed with the A by the fourth valve The circulating water inlet of the device is connected, and the circulating water outlet of the A condensation heat exchanger is connected to the inlet of the A-peak cooling tower through the fifth valve. The output port of the A-peak cooling tower passes through the A-peak cooling water circulation pump and the sixth valve and A in turn. The circulating water inlet of the condensation heat exchanger is connected; the exhaust steam exhaust pipe of the B direct air cooling unit communicates with the steam inlet of the B condensation heat exchanger through the seventh valve, and is condensed by heat transfer and then sequentially passes through B condensation. Eighth threshold gate provided on the heat hydrophobic port, the input port of the second three-way exhaust apparatus and a ninth gate width B with direct air cooling unit communication; heat circulation pump outlet through tenth valve and condensate B The circulating water inlet of the junction heat exchanger is connected, and the circulating water outlet of the B condensation heat exchanger is connected to the inlet of the B-peak cooling tower through the eleventh valve, and the output of the B-peak cooling tower passes through the B-peak cooling water circulation pump and the first The twelve wide door is connected to the circulating water inlet of the B condensation heat exchanger; a communication pipe is arranged between the inlet of the A condensation heat exchanger and the inlet of the B condensation heat exchanger, and the first pipe is provided with a communication pipe A fifteenth valve; a second communication tube is disposed between the first three-way and the second three-way, and a sixteenth wide door is disposed on the second communication tube.

The circulating water outlet of the A condensation heat exchanger is in communication with the first heating pipeline, and the thirteenth valve is disposed on the first heating pipeline; the circulating water outlet of the B condensation heat exchanger and the first The two heating pipelines are connected to the pipeline, and the fourteenth valve is arranged on the second heating pipeline.

On the vacuuming port of the A condensing heat exchanger, an A vacuuming tube is arranged, and the 17th wide door, the third three-way and the eighteenth valve are sequentially arranged on the A vacuuming pipe; the vacuuming in the B condensation heat exchanger a B vacuum pump is arranged on the mouth, and a nineteenth valve, a fourth three-way and a twentieth valve are arranged in sequence on the B vacuum pumping tube; a third communicating tube is arranged between the third three-way and the fourth three-way, A twenty-first valve is disposed on the third communication pipe. The invention relates to a composite condensing heat exchange system for recovering waste heat from steam exhaust of a direct air-cooled steam turbine and performing peak cooling in summer, which can respectively meet the energy-saving technology for waste heat recovery and peak cooling in winter, and comprehensively consider two functions for the system. Design, can achieve the purpose of reducing investment and improving equipment utilization. BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a schematic view showing the structure of a system of the present invention. BEST MODE FOR CARRYING OUT THE INVENTION The present invention will be described below with reference to the accompanying drawings: A direct air-cooled steam turbine composite condensing heat exchange system, including A condensing heat exchanger 1, B condensing heat exchanger 2, heating network circulating pump 5, A peak cooling tower 3. B-peak cooling tower 4, A-peak cooling water circulation pump 6 and B-peak cooling water circulation pump 7, A direct air-cooling unit's exhaust steam exhaust pipe 29 is connected to the inlet port of the A condensation heat exchanger 1 through the first valve 8 After being condensed by heat exchange, the second door 24, the first three-way 36 and the third valve 25 disposed on the drain port of the A condensing heat exchanger 1 are in communication with the input port of the exhaust device 30 of the direct air-cooling unit of the A; The outlet of the heat network circulation pump 5 is connected to the circulating water inlet of the A condensation heat exchanger 1 through the fourth valve 11, and the circulating water outlet of the condensation heat exchanger 1 of A is cooled by the fifth valve 14 and the A peak. While the inlet of the tower 3 is connected, the output port of the A-peak cooling tower 3 is in turn connected to the circulating water inlet of the A condensing heat exchanger 1 through the A-peak cooling water circulation pump 6 and the sixth valve 13.

The exhaust steam exhaust pipe 31 of the B direct air cooling unit communicates with the steam inlet of the B condensation heat exchanger 2 through the seventh valve 9, and passes through the heat exchange condensation, and sequentially passes through the eighth valve disposed on the drain port of the B condensation heat exchanger 2. 27. The second three-way 37 and the ninth wide door 28 are in communication with the input port of the exhaust unit 32 of the direct air cooling unit of the B; the outlet of the heat network circulating pump 5 passes through the tenth valve 15 and the circulating water of the B condensation heat exchanger 2 The inlet port is connected, and the circulating water outlet of the B condensation heat exchanger 2 is connected to the inlet of the B peak cooling tower 4 through the eleventh valve 18, and the output port of the B peak cooling tower 4 sequentially passes through the B peak cooling water circulation pump 7 and the twelfth The valve 17 is in communication with the circulating water inlet of the B condensation heat exchanger 2.

The circulating water outlet of the condensing heat exchanger 1 is in communication with the first heating pipe conveying pipe 33, and the thirteenth valve 12 is disposed on the first heating pipe conveying pipe 33;

The circulating water outlet of the B condensation heat exchanger 2 is in communication with the second heating pipe delivery pipe 34, and the fourteenth valve 16 is disposed on the second heating pipe conveying pipe 34. A communication pipe 35 is disposed between the inlet of the A condensation heat exchanger 1 and the inlet of the B condensation heat exchanger 2, and the fifteenth valve 10 is disposed on the communication pipe 35; A second communication tube 38 is disposed between the second three passages 37, and a sixteenth door 26 is disposed on the second communication tube 38.

On the vacuuming port of the A condensing heat exchanger 1, an A vacuuming pipe 41 is disposed, and a seventeenth valve 20, a third three-way 39 and an eighteenth door 19 are sequentially disposed on the A vacuuming pipe 41; A vacuum pumping tube 42 is disposed on the vacuuming port of the heat exchanger 2, and a nineteenth valve 23, a fourth three-way 40 and a second tenth door 22 are sequentially disposed on the B vacuuming pipe 42; in the third three-way 39 A third communication pipe 43 is disposed between the fourth tee 40 and a second eleventh door 21 is disposed on the third communication pipe 43.

During the heating period in winter, when the waste heat of the A direct air cooling unit is recovered: the first valve 8 is opened, the seventh valve 9 and the fifteenth threshold door 10 are closed, so that the whole system works in a towed state, that is, Only the residual heat of the A direct air cooling unit is recovered; at the same time, the fourth valve 11, the thirteenth valve 12, the tenth door 15 and the fourteenth valve 16 are opened, and the heat network circulating pump 5 will be connected to the first heating pipe. The conveying pipe 33 performs hot water supply, and the water pumped into the A condensing heat exchanger 1 absorbs heat and then supplies hot water to the first heating pipe conveying pipe 33 through the thirteenth valve 12; at the same time, the heating network circulates The pump 5 will also supply hot water to the second heating pipe transfer pipe 34, and pump it through the tenth valve 15 to the B condensing heat exchanger ² The water in the water supplies the hot water to the second heating pipe transfer pipe 34 through the fourteenth valve 16; the sixth door 13, the fifth door 14, the twelfth valve 17, and the eleventh valve 18 are closed to make the peak The cooling water system does not work; the second valve 24, the third threshold door 25, the sixteenth valve 26 and the eighth valve 27 are opened, the ninth valve 28 is closed, and the A condensing heat exchanger 1 and the B condensing heat exchanger 2 pass the above The valve is hydrophobic; the eighteenth valve 19, the seventeenth valve 20, the twenty-first wide door 21 and the nineteenth valve 23 are opened, the twentyth valve 22 is closed, the A condensation heat exchanger 1 and the B condensation heat exchanger 2 Vacuuming through the above valve. During the heating period in winter, when the waste heat of the B direct air cooling unit is recovered - the seventh valve 9 is opened, the first valve 8 and the fifteenth valve 10 are closed, so that the whole system works in one to two working state, that is, only The waste heat of the B direct air cooling unit is recovered; at the same time, the fourth valve 11, the thirteenth valve 12, the tenth valve 15 and the fourteenth valve 16 are opened, and the heat network circulation pump 5 will be connected to the first heating pipe 33. The hot water supply is performed, and the water pumped into the A condensation heat exchanger 1 supplies hot water to the first heating pipe delivery pipe 33 through the thirteenth valve 12; at the same time, the heat network circulation pump 5 is also paired with the second The heating pipe conveying pipe 34) performs hot water supply, and the water pumped into the B condensing heat exchanger 2 through the tenth valve 15 absorbs heat and passes through the fourteenth wide door 16 to the second heating pipe conveying pipe 34. Heating water supply; closing the sixth valve 13, the fifth valve 14, the twelfth valve 17 and the eleventh valve 18, so that the peak cooling water system does not work; opening the ninth valve 28, the third valve 25, the sixteenth valve 26 and the eighth valve 27, the second valve 24 is closed, the A condensing heat exchanger 1 and the B condensing heat exchanger 2 are connected The above valve is hydrophobic; the twentyth valve 22, the seventeenth valve 20, the twenty-first door 21 and the nineteenth door 23 are opened, the eighteenth valve 19 is closed, and the A condensation heat exchanger 1 and B are condensed The heater 2 is evacuated through the above valve. During peak summer periods, when peak cooling is required:

The fourth valve 11, the thirteenth valve 12, the tenth valve 15 and the fourteenth valve 16 of the hot water circulating water system are simultaneously closed, the sixth wide door 13, the fifth threshold door 14, the twelfth of the peak cooling water system The wide door 17 and the eleventh valve 18 are simultaneously opened, the fifteenth valve 10 as a steam supply contact valve is closed, and the twenty-first valve 21 as a vacuum contact is closed; the sixteenth threshold door 26 as a hydrophobic communication threshold Closed, the system is in a one-to-one working state, that is, two air-cooling units respectively drive the respective condensing heat exchanger and the peak cooling tower to work, so that the problem of high back pressure of the direct air-cooling unit in summer is fundamentally solved. During the peak load operation load of the unit and the return water temperature of the hot network circulating water, the temperature rise of the hot network circulating water in the condensing heat exchanger is between 10 °C and 20 °C, and the circulation of the mechanical ventilation cooling tower Water cooling capacity is generally 18 Within °C, therefore, the flow design of the peak cooling water of the condensing heat exchanger and the circulating water of the heating network can be approximated. The external heat supply of the unit is deteriorated. The back pressure operation range is between 25 and 35 kPa, and the operating back pressure of the peak cooler is generally between 15 and 25 kPa, to meet the waste heat recovery system for heating system design. The single-machine peak cooling system has a steam extraction capacity of only 50% of the waste heat recovery system to meet the heat recovery system design of the waste heat recovery system. The present invention can meet the requirements of the peak cooling system. The main equipment of the invention comprises two condensation heat exchangers, two peak coolers, 3-5 heat network circulation pumps, and two peak cooling water circulation pumps. The condensing heat exchanger is the core equipment of the system. When it is used as the exhaust steam heat recovery device, the hot water circulating water back to the water is pressurized by the heat network pump and then enters the condensing heat exchanger to heat the recovered waste heat, and then continues to the conventional heat network. After the heating reaches the required temperature, external heat is supplied; the amount of waste heat recovery can be adjusted by changing the back pressure of the unit. When the condensing heat exchanger is used as a peak cooling device, the condensing heat exchanger and the mechanical ventilation cooling tower form a closed circulating cooling water system, and a part of the exhaust steam is extracted for cooling, and the air cooling is reduced by reducing the heat load of the air cooling radiator. The purpose of the unit operating back pressure.

During the heating period in winter, one unit deteriorates the back pressure to heat the return water, and the other unit heats the operation mode of the conventional heater. This method can fully absorb the residual heat of the single unit, which can improve the operation of the two units as a whole. Economic. During summer operation, the peak cooling system operates in a unit that allows the two units to control the operating back pressure requirements. In order to achieve the above functions, the steam supply system, the air extraction system and the drainage system of the two condensing heat exchangers are all set up with the switching master control mode, which can respectively meet the waste heat recovery of the two units' single-unit heating operation.

Claims

Rights request

1. A direct air-cooled steam turbine combined condensing heat exchange system, comprising an A condensing heat exchanger (1), a B condensing heat exchanger (2), a heating network circulating pump (5), an A peak cooling tower (3), B-peak cooling tower (4), A-peak cooling water circulation pump (6) and B-peak cooling water circulation pump (7), characterized in that the direct steam exhaust pipe (29) of the A direct air cooling unit passes through the first valve (8) Connected with the inlet port of the A condensation heat exchanger (1), and after condensation by heat exchange, sequentially passes through the second valve (24), the first three-way (36) and the first port (36) disposed on the hydrophobic port of the condensation heat exchanger (1) The third valve (25) is in communication with the input port of the exhaust unit (30) of the A direct air cooling unit; the outlet of the hot network circulating pump (5) is circulated through the fourth valve (11) and the A condensation heat exchanger (1) The water inlet is connected, and the circulating water outlet of the A condensation heat exchanger (1) is connected to the inlet of the A peak cooling tower (3) through the fifth valve (14), and the output of the A peak cooling tower (3) passes through the A spike in turn. Circulating water for cooling water circulation pump (6) and sixth threshold door (13) and A condensation heat exchanger (1) The inlet is connected; the exhaust steam exhaust pipe (31) of the B direct air cooling unit is connected to the steam inlet of the B condensing heat exchanger (2) through the seventh door (9), and is condensed by B after condensation heat transfer. The eighth valve (27), the second three-way (37) and the ninth valve (28) disposed on the drain port of the device (2) are in communication with the input port of the exhaust device (32) of the B direct air-cooling unit; The outlet of the pump (5) is connected to the circulating water inlet of the B condensation heat exchanger (2) through the tenth wide door (15), and the circulating water outlet of the B condensation heat exchanger (2) passes through the eleventh valve (18) ) Connected to the inlet of the B-peak cooling tower (4), the output of the B-peak cooling tower (4) passes through the B-peak cooling water circulation pump (7) and the twelfth valve (17) and the B condensation heat exchanger (2) The circulating water inlet is connected; a communication pipe (35) is disposed between the inlet of the A condensation heat exchanger (1) and the inlet of the B condensation heat exchanger (2), and the communication pipe (35) is provided with The fifteenth door (10); a second communication pipe (38) is disposed between the first three-way (36) and the second three-way (37), in the second connection It is provided with a sixteenth gate width (26) of the tube (38).

2. A direct air-cooled steam turbine composite condensing heat exchange system according to claim 1, characterized in that: a circulating water outlet of the condensing heat exchanger (1) and a first heating pipeline (33) Connected, a thirteenth valve (12) is disposed on the first heating pipe (33); a circulating water outlet of the B condensation heat exchanger (2) and a second heating pipe (34) Connected, a fourteenth valve (16) is disposed on the second heating pipe (34). 3. A direct air-cooled steam turbine combined condensing heat exchange system according to claim 2, wherein an A vacuuming pipe (41) is disposed on the vacuuming port of the A condensing heat exchanger (1). The seventh vacuum pump (41) is provided with a seventeenth valve (20), a third three-way (39) and an eighteenth valve (19); in the vacuum port of the B condensation heat exchanger (2), B vacuum tube (42), in B vacuum tube

(29) a nineteenth threshold gate (23), a fourth three-way (40), and a twentieth valve (22) are sequentially disposed; between the third three-way (39) and the fourth three-way (40) A third communication pipe (43) is disposed, and a twenty-first valve (21) is disposed on the third communication pipe (43).