CN103075216B - Brayton-cascade steam Rankine combined cycle power generation system - Google Patents

Brayton-cascade steam Rankine combined cycle power generation system Download PDF

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CN103075216B
CN103075216B CN201310029364.8A CN201310029364A CN103075216B CN 103075216 B CN103075216 B CN 103075216B CN 201310029364 A CN201310029364 A CN 201310029364A CN 103075216 B CN103075216 B CN 103075216B
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steam
pressure
low
voltage terminal
rankine cycle
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CN103075216A (en
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王海波
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Nanjing Reclaimer Environmental Technology Co Ltd
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Nanjing Reclaimer Environmental Technology Co Ltd
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    • YGENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
    • Y02TECHNOLOGIES OR APPLICATIONS FOR MITIGATION OR ADAPTATION AGAINST CLIMATE CHANGE
    • Y02EREDUCTION OF GREENHOUSE GAS [GHG] EMISSIONS, RELATED TO ENERGY GENERATION, TRANSMISSION OR DISTRIBUTION
    • Y02E20/00Combustion technologies with mitigation potential
    • Y02E20/14Combined heat and power generation [CHP]
    • YGENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
    • Y02TECHNOLOGIES OR APPLICATIONS FOR MITIGATION OR ADAPTATION AGAINST CLIMATE CHANGE
    • Y02EREDUCTION OF GREENHOUSE GAS [GHG] EMISSIONS, RELATED TO ENERGY GENERATION, TRANSMISSION OR DISTRIBUTION
    • Y02E20/00Combustion technologies with mitigation potential
    • Y02E20/16Combined cycle power plant [CCPP], or combined cycle gas turbine [CCGT]
    • YGENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
    • Y02TECHNOLOGIES OR APPLICATIONS FOR MITIGATION OR ADAPTATION AGAINST CLIMATE CHANGE
    • Y02EREDUCTION OF GREENHOUSE GAS [GHG] EMISSIONS, RELATED TO ENERGY GENERATION, TRANSMISSION OR DISTRIBUTION
    • Y02E60/00Enabling technologies; Technologies with a potential or indirect contribution to GHG emissions mitigation
    • Y02E60/16Mechanical energy storage, e.g. flywheels or pressurised fluids

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Abstract

The invention relates to a Brayton-cascade steam Rankine combined cycle power generation system. The gas exhaust of a Brayton cycle is adopted as a heat source for a high-temperature end steam Rankine cycle, a steam condenser in a high-pressure end steam Rankine cycle is adopted as one of heat sources for a low-pressure end steam Rankine cycle, the latent heat of vaporization of the steam in the high-pressure end steam Rankine cycle is efficiently recovered to be used for power generation in the low-pressure end steam Rankine cycle, consequently, the load of the steam condenser of the conventional steam Rankine cycle system can be effectively reduced by more than absolute 20 percent, and by adopting a system optimization technique, the absolute thermal efficiency of the cycles of the whole system can be increased by more than 5 percent. The Brayton-cascade steam Rankine combined cycle power generation system not only can be used in the energy-saving alteration of conventional units, but also can be used in the design and construction of new units, and economic, social and environmental protection benefits are remarkable.

Description

Brayton-cascade steam Rankine combined cycle generating unit
Technical field
The present invention relates to a kind of Brayton-cascade steam Rankine combined cycle generating unit, concrete genus thermal power plant field of power equipment technology.
Background technique
Combustion gas one Steam Combined Cycle is because of series of advantages such as its thermal efficiency are high, toggle speed is fast, environmental protection condition is good, installation period is short, investment cost is low, add the develop rapidly of gas turbine technology in recent years, gas turbine single-machine capacity also continues to increase, and combined cycle research has caused attention and the enforcement of countries in the world.
The research of external combined cycle generation technology starts from eighties of last century end of the sixties, through the development of decades, at present, the combustion gas one steam combined cycle power generating technology comparative maturity of many developed countries such as the U.S., Britain, Japan, its power supply efficiency reaches more than 50%.If U.S. CE company is about 53%; ABB AB is 48% ~ 51.9%; Mitsubishi Heavy Industries Ltd are 5l% ~ 52%.Many companies (as Texco company of the U.S., Belgian CMI company etc.) all have the Combined Cycle Heat Recovery Boiler performance design of comparative maturity, system optimization, structure optimization, manufacturing technology, and have grasped thermodynamic property and the roadability of Combined Cycle Heat Recovery Boiler completely.The extraction cycle of Gas-steam Combined Cycle and the at present Cheng's cycle of two-fluid circulation-steam injected gas turbine just under development and the blower outlet water-spraying evaporation at gas turbine, the representative of this technical development just, the former is full-fledged, achieve huge economic benefit, rear both are stepping up among research, and Cheng's cycle has application example and formal product.
Taking water vapor as the thermal power plant of working medium, is to carry out thermal energy to become mechanical energy on a large scale, and the factory transformed mechanical energy into electricity again.The circulation of power station application is very complicated, but in essence, the Rankine cycle be mainly made up of equipment such as boiler, steam turbine, vapour condenser, water pumps has come, its working principle is: feedwater first sends into boiler after feed water pump pressurization, water is by superheated vapor that is heat vaporized, that form High Temperature High Pressure in the boiler, superheated vapor is expansion work in steam turbine, become the exhaust steam of low-temp low-pressure, finally enter vapour condenser and be condensed into condensed water, again through water pump, condensed water is sent into boiler and carry out new circulation.As for the complex loops that thermal power plant uses, only on Rankine cycle basis, in order to improve the thermal efficiency, improved and the new circulation that formed and extraction cycle, reheat vapor cycle etc., Rankine cycle has become the basic circulation of modern vapor power plant.
Modern big-and-middle-sized steam power plant all adopts heated feed water extraction cycle, the steam reheat vapor cycle technology of drawing gas without any exception, thus improve heating mean temperature, except considerably improving thermal efficiency of cycle, though specific steam consumption increases to some extent, but make steam discharge rate reduce owing to drawing gas step by step, this is conducive to the ratio i.e. internal efficiency ratio η of this circulation of actual acting amount and theoretical acting amount oiraising, solve simultaneously large steam turbine exhaust stage blade negotiability restriction difficulty, vapour condenser volume also can correspondingly reduce.But still discharge a large amount of latent heats of vaporization when steam condenses in vapour condenser, need a large amount of water or air to cool, namely waste heat, cause thermo-pollution, waste again electric energy, water resources.Therefore how effectively to utilize a large amount of latent heat of vaporization discharged during steam condensation in vapour condenser, be worth further investigation.
Give off a large amount of low-temperature flue gas in station boiler production process, wherein the heat of recoverable is a lot.Although the waste of this part residual heat resources is huge, recycle and have larger difficulty, its main cause is: the quality of (1) waste heat is lower, does not find effective Application way; (2) reclaim the waste heat of this part, often larger change is made to the original thermodynamic system of boiler, there is certain risk; (3) thermal balance question is difficult to tissue, is difficult to all directly utilize in inside plants, often needs outwards to find suitable heat user, and heat user often have fluctuation by heat load, thus limit the versatility of recovery method.
Therefore the thermomechanics basic law in steam Rankine cycle, Gas-steam Combined Cycle, Cheng's cycle thermal power plant how is utilized, retain the advantage based on the power plant technology of Rankine cycle principle, inquire into new combined cycle theoretical, really find the new way increasing substantially the combined circulation power apparatus thermal efficiency, become the difficult point of this area research.
Summary of the invention
Object of the present invention is for solving above-mentioned steam Rankine cycle and combined cycle generating unit Problems existing, a kind of new thermal power plant's combined cycle flow process is proposed, i.e. Brayton-cascade steam Rankine combined cycle generating unit, can while the advantage retaining traditional steam Rankine cycle technology, significantly reclaim the latent heat of vaporization of conventional vapor Rankine cycle vapour condenser, the load of traditional Rankine cycle vapour condenser is alleviated by a relatively large margin, when identical generated energy, the absolute amplitude value alleviated can reach 20%, thus realize the thermal efficiency effectively improving whole Combined Cycle Unit, finally reach energy-saving and cost-reducing, improve the object of system thermal efficiency.
The object of the invention is to be realized by following measures:
A kind of Brayton-cascade steam Rankine Rankine combined cycle cogeneration device, this device comprises Boulez and to pause circulation, the Rankine cycle of high voltage terminal steam, low voltage terminal steam Rankine cycle system, it is characterized in that:
Air 23 sends into fuel-burning equipment 25 through gas compressor 24, and with fuel 28 Thorough combustion entered, the high-temperature flue gas of generation enters gas turbine 26, drags gas turbine powered generator 29 and generates electricity, complete gas turbine unit Boulez and to pause circulation.
Described gas turbine 26 high-temperature flue gas 27 of discharging is as the thermal source of cascade type steam Rankine cycle system, and high-temperature flue gas 27 is discharged after exhaust heat boiler body 1, low-pressure superheater 15, high-pressure superheater 3, high-pressure feed-water heater 8, low-pressure feed heater 11 are lowered the temperature along flue 22.
Described high voltage terminal steam Rankine cycle, refers to by exhaust heat boiler body 1 saturated vapour 2 out, forms high pressure superheated steam 3-1 through high-pressure superheater 3, sends into the generating of high-pressure turbine 4 drive electrical generators; High-pressure turbine 4 exhaust steam out condenses into water of condensation 6 at high pressure vapour condenser 5, water of condensation 6 sends into high-pressure feed-water heater 8, exhaust heat boiler body 1 through high pressure water pump 7, exhaust heat boiler body 1 produces saturated vapour again, thus forms high voltage terminal steam Rankine cycle circuit.
Described low voltage terminal steam Rankine cycle, refers to by low pressure evaporator 14 steam out, forms low-pressure superheated steam 16 through low-pressure superheater 15, sends into the generating of low-pressure turbine 17 drive electrical generators; Low-pressure turbine 17 exhaust steam out condenses into low voltage terminal water of condensation 9 at low pressure vapour condenser 18, water of condensation 9 is through condensate pump 10, low-pressure feed heater 11, oxygen-eliminating device 12, low pressure feed water pump 13, send into low pressure evaporator 14, low pressure evaporator 14 produces steam again, thus forms low voltage terminal steam Rankine cycle circuit.
The steam condensation side of described high pressure vapour condenser 5 adopts operation under positive pressure mode, i.e. the pressure of high-pressure turbine 4 exhaust steam is out higher than atmospheric pressure.
The high pressure vapour condenser 5 i.e. low pressure evaporator 15 of low voltage terminal steam Rankine cycle circuit of described high voltage terminal steam Rankine cycle circuit, thus by the Rankine cycle of temperature end steam together with low-temperature end steam Rankine cycle organic composite, the latent heat of vaporization discharged during the steam-condensation of high efficiente callback temperature end steam Rankine cycle generates electricity for the Rankine cycle of low-temperature end steam.
When described low-pressure feed heater 11 and flue gas adopt separated type heat exchange mode, low-pressure feed heater is compound phase change heat exchanger, comprises vaporizer 11-1, condenser 11-2, vaporizer 11-1 and condenser employing is split type or the structure of integral type; Phase-change working substance wherein adopts water or other suitable materials; The heat that phase-change working substance absorbs flue gas in vaporizer 11-1 produces saturated vapour, saturated vapour is by condenser 11-2 and low voltage terminal water of condensation 9 wall-type heat exchange, form condensation water is absorbed flue gas again heat generation steam by vaporizer 11-1 after cooling, thus form the inner cyclic process of phase-change working substance; Phase-change working substance adopts natural circulation or pump circulation mode; Preferred method is vaporizer, the split type layout of condenser, and namely vaporizer 11-1 is arranged in flue 22, condenser 11-2 is arranged in outside flue, and phase-change working substance adopts water, adopts natural circulation mode.
Be provided with the water charging system supporting with cascade type steam Rankine combined cycle generating unit, the qualified moisturizing through Water Treatment enters oxygen-eliminating device 12, the consumption of replenishment system; Be provided with the moisturizing loop of high voltage terminal steam Rankine cycle: the low pressure feed water after oxygen-eliminating device 12 deoxygenation fills into high voltage terminal steam Rankine cycle system through high voltage terminal small pump 20, high voltage terminal moisturizing pipeline.
Described high-pressure feed-water heater 8, high pressure vapour condenser 5(and low pressure evaporator 14), low-pressure feed heater 11, high-pressure superheater 3, low-pressure superheater 15 can arrange one or more respectively, adopts series, parallel or series-parallel connection mode to connect.
Described low voltage terminal vapour condenser 18 conveniently technology is arranged, and adopts water or air etc. as cooling medium.
The heat-exchanging element of aforementioned device mentioned in the present invention can adopt tubulation, fin tube, coiler or spiral groove pipe, or adopts the pipe of other augmentation of heat transfer measures or the hollow cavity heat-exchanging element of other patterns.
Control a little higher than flue gas acid dew point temperature of wall surface temperature of the vaporizer 11-1 heat exchanger surface of low-pressure feed heater 11, or adopt corrosion-resistant material effectively to alleviate the cold end corrosion of flue gas, can effectively reduce temperature of exhaust fume, avoid flue gas low-temperature corrode while, high efficiente callback fume afterheat.
Unaccounted equipment and standby system, pipeline, instrument, valve in the present invention, be incubated, there is regulatory function bypass facility etc. adopt known mature technology to carry out supporting.
Be provided with the safety supporting with present system, regulating controller, the known Mature Regulation technology of existing steam Rankine cycle power station, Cheng's cycle power station or gas-steam combined cycle power plant is adopted to carry out supporting, Brayton-cascade steam Rankine combined cycle generating unit energy economy, safety, high thermal efficiency are run, reaches energy-saving and cost-reducing object.
the present invention compared to existing technology tool has the following advantages:
1, the Brayton-cascade steam Rankine combined cycle generating unit of the present invention's design, be different from traditional gas-steam combined cycle system, wherein the high pressure vapour condenser 5 steam-condensation side of high voltage terminal steam Rankine cycle adopts operation under positive pressure mode, using the thermal source one of of the steam discharge of high-pressure turbine 4 as the Rankine cycle of low voltage terminal steam, be combined with each other ingenious for the low pressure evaporator 14 in high pressure vapour condenser 5 and the Rankine cycle of low voltage terminal steam, in the Rankine cycle of high voltage terminal steam, the latent heat of vaporization of steam is all utilized effectively, compare the load of the low voltage terminal vapour condenser of the unit of same generated output, the absolute amplitude value that the load of vapour condenser alleviates can reach 40%, the absolute efficiency value of whole system circulation at least can improve more than 3%, back pressure because of high voltage terminal steam Rankine cycle steam turbine adopts malleation mode to run, high-pressure turbine outlet exhaust steam can ensure certain degree of superheat, when high voltage terminal superheat steam temperature is constant, method by suitably improving the first pressing of high voltage terminal steam improves thermal efficiency of cycle more than 2% further, and due to steam turbine outlet exhaust steam specific volume diminish, reduce the size of equipment.
2, the equipment of steam Rankine cycle system and capital investment decrease, and the operating cost of whole Combined Cycle Unit reduces significantly:
(1) vapour condenser of high voltage terminal steam Rankine cycle system is owing to adopting operation under positive pressure mode, eliminate that traditional negative pressure operation technique inevitably leaks gas, water leakage phenomenon, the feedwater deaeration load of the oxygen-eliminating device of supporting whole Rankine cycle system significantly alleviates, deaeration plant capacity is little, compare the large high-rise arrangement space of traditional oxygen-eliminating device, required space is little, and flexible arrangement is convenient;
(2) much smaller than traditional vapour condenser of low pressure vapour condenser, absolute amplitude value reduces about 40%.
3, the low-temperature flue gas waste heat of power plant realizes high efficiente callback utilization: during the heat exchanger employing phase-change heat-exchanger that back-end ductwork is arranged, can the waste heat of high efficiente callback flue gas, when acid dew-point temperature is lower, temperature of exhaust fume can be reduced to about 120 DEG C, during phase-change heat-exchanger vaporizer employing resistant material, temperature of exhaust fume can reduce more, reach about 85 DEG C, very favourable to the operation of system for desulfuration and denitration, while effectively avoiding flue gas low-temperature to corrode, the heat reclaimed is used for Rankine cycle system efficiency power generation, more meets cascaded utilization of energy principle.
4, safety in operation significantly improves:
(1) the high-pressure steam turbine operation under positive pressure of high voltage terminal steam Rankine cycle, outlet vapor is superheated vapor, compared to the unit adopting reheat vapor cycle technology, can reduce back pressure further, thus multiple electricity, the operating conditions of steam turbine is optimized; Low-pressure superheater in the Rankine cycle of low voltage terminal steam, because pressure is lower, safety in operation improves; The admission of low-pressure turbine adopts the superheated vapor through reheating, effectively can increase the mass dryness fraction of low-pressure turbine steam discharge, effectively can solve the problem that in conventional vapor Rankine cycle, last stage vane of steam turbine brings because of wet vapor to design, manufacture and operation problem, obviously improve before the vibration comparatively of steam turbine generator set.
(2) the oxygen corrosion Safety performance of high pressure side steam Rankine cycle steam generator system is obviously improved, and alleviates conventional vapor generator set because of the operation of vapour condenser negative pressure, the oxygen corrosion harm that air unavoidably bleeds and causes service system.
5, the solution of the present invention both can be used for design, the construction of newly-built power plant system, also can be used for the reducing energy consumption to existing Rankine cycle unit, the potentiality of the abundant excavating device of energy, vitalize existing assets, meet the industrial policy of country simultaneously, economical, the Security of unit operation obtain Reliable guarantee, effectively can improve the thermal efficiency of system.
Accompanying drawing explanation
Fig. 1 is a kind of Brayton-cascade steam Rankine combined cycle generating unit schematic flow sheet of the present invention.
In Fig. 1: 1-boiler body, 2-saturated vapour, 3-high-pressure superheater, 3-1-high pressure superheated steam, 4-high-pressure steam turbine, 5-high pressure vapour condenser, 6-water of condensation, 7-high pressure water pump, 8-high-pressure feed-water heater, 9-low pressure condensate water, 10-condensate pump, 11-low-pressure feed heater, 11-1-vaporizer, 11-2-condenser, 12-oxygen-eliminating device, 13-low pressure feed water pump, 14-low voltage terminal vaporizer, 15-low-pressure superheater, 16-low-pressure superheated steam, 17-low-pressure turbine, 18-low pressure vapour condenser, 19-generator, 20-high voltage terminal small pump, 21-high voltage terminal moisturizing pipeline, 22-flue, 23-air, 24-gas compressor, 25-fuel-burning equipment, 26-gas turbine, 27-high-temperature flue gas, 28-fuel, 29-gas turbine powered generator.
Embodiment
Below in conjunction with the drawings and specific embodiments, the present invention is described in further detail.
embodiment 1:
As shown in Figure 1, a kind of Brayton-cascade steam Rankine combined cycle cogeneration device, this device comprises Boulez and to pause circulation, the Rankine cycle of high voltage terminal steam, the Rankine cycle of low voltage terminal steam:
Air 23 sends into fuel-burning equipment 25 through gas compressor 24, and with fuel 28 Thorough combustion entered, the high-temperature flue gas of generation enters gas turbine 26, drags gas turbine powered generator 29 and generates electricity, complete gas turbine unit Boulez and to pause circulation.
Described high voltage terminal steam Rankine cycle, refers to by exhaust heat boiler body 1 saturated vapour 2 out, forms high pressure superheated steam 3-1 through high-pressure superheater 3, sends into the generating of high-pressure turbine 4 drive electrical generators; High-pressure turbine 4 exhaust steam out condenses into water of condensation 6 at high pressure vapour condenser 5, water of condensation 6 sends into high-pressure feed-water heater 8, exhaust heat boiler body 1 through high pressure water pump 7, exhaust heat boiler body 1 produces saturated vapour again, thus forms high voltage terminal steam Rankine cycle circuit.
Described low voltage terminal steam Rankine cycle, refers to by low pressure evaporator 14 steam out, forms low-pressure superheated steam 16 through low-pressure superheater 15, sends into the generating of low-pressure turbine 17 drive electrical generators; Low-pressure turbine 17 exhaust steam out condenses into low voltage terminal water of condensation 9 at low pressure vapour condenser 18, water of condensation 9 is through condensate pump 10, condenser 11-2, oxygen-eliminating device 12, low pressure feed water pump 13, send into low pressure evaporator 14, low pressure evaporator 14 produces steam again, thus forms low voltage terminal steam Rankine cycle circuit.
The steam condensation side of described high pressure vapour condenser 5 adopts operation under positive pressure mode, i.e. the pressure of high-pressure turbine 4 exhaust steam is out higher than atmospheric pressure.
The high pressure vapour condenser 5 i.e. low pressure evaporator 15 of low voltage terminal steam Rankine cycle circuit of described high voltage terminal steam Rankine cycle circuit, thus by the Rankine cycle of temperature end steam together with low-temperature end steam Rankine cycle organic composite, the latent heat of vaporization discharged during the steam-condensation of high efficiente callback temperature end steam Rankine cycle generates electricity for the Rankine cycle of low-temperature end steam.
Described gas turbine 26 high-temperature flue gas 27 of discharging is as the thermal source of cascade type steam Rankine cycle system, and high-temperature flue gas 27 is discharged after the vaporizer 11-1 of exhaust heat boiler body 1, low-pressure superheater 15, high-pressure superheater 3, high-pressure feed-water heater 8, low-pressure feed heater 11 lowers the temperature along flue 22.
Described low-pressure feed heater 11 adopts separated type heat exchange mode with flue gas, for compound phase change heat exchanger, comprise vaporizer 11-1, condenser 11-2, vaporizer 11-1 is arranged in flue 22, condenser 11-2 is arranged in outside flue, phase-change working substance adopts water, adopts natural circulation mode.The heat that phase-change working substance absorbs flue gas in vaporizer 11-1 produces saturated vapour, saturated vapour is by condenser 11-2 and low voltage terminal water of condensation 9 wall-type heat exchange, form condensation water is absorbed flue gas again heat generation steam by vaporizer 11-1 after cooling, thus form the inner cyclic process of phase-change working substance.
Be provided with the water charging system supporting with cascade type steam Rankine combined cycle generating unit, the qualified moisturizing through Water Treatment enters oxygen-eliminating device 12, supplements the consumption of whole Rankine cycle system feedwater; Be provided with the moisturizing loop of high voltage terminal steam Rankine cycle: low pressure feed water pump 13 exports the make-up water of drawing fills into the high pressure water pump 7 of high voltage terminal steam Rankine cycle system inlet line through high voltage terminal small pump 20, high voltage terminal moisturizing pipeline.
Described high-pressure feed-water heater 8, high pressure vapour condenser 5(and low pressure evaporator 14), low-pressure feed heater 11, high-pressure superheater 3, low-pressure superheater 15 can arrange one or more respectively, adopts series, parallel or series-parallel connection mode to connect.
Described low voltage terminal vapour condenser 18 conveniently technology is arranged, and adopts water as cooling medium.
The heat-exchanging element of aforementioned device mentioned in the present invention can adopt tubulation, fin tube, coiler or spiral groove pipe, or adopts the pipe of other augmentation of heat transfer measures or the hollow cavity heat-exchanging element of other patterns.
Control a little higher than flue gas acid dew point temperature of wall surface temperature of the vaporizer 11-1 heat exchanger surface of low-pressure feed heater 11, or adopt corrosion-resistant material effectively to alleviate the cold end corrosion of flue gas, can effectively reduce temperature of exhaust fume, avoid flue gas low-temperature corrode while, high efficiente callback fume afterheat.
Unaccounted equipment and standby system, pipeline, instrument, valve in the present invention, be incubated, there are regulatory function bypass, safety protection device etc. adopt known mature technology to carry out supporting.
Be provided with the safety supporting with present system, regulating controller, the known Mature Regulation technology of existing steam Rankine cycle power station, Cheng's cycle power station or gas-steam combined cycle power plant is adopted to carry out supporting, cascade type steam Rankine combined cycle generating unit energy economy, safety, high thermal efficiency are run, reaches energy-saving and cost-reducing object.
Although the present invention with preferred embodiment openly as above, they are not for limiting the present invention, being anyly familiar with this those skilled in the art, without departing from the spirit and scope of the invention, from ought making various changes or retouch, belong to the protection domain of the present invention equally.What therefore protection scope of the present invention should define with the claim of the application is as the criterion.

Claims (3)

1. a Brayton-cascade steam Rankine combined cycle generating unit, this device comprises Boulez and to pause circulation, the Rankine cycle of high voltage terminal steam and low voltage terminal steam Rankine cycle system, it is characterized in that:
Air (23) sends into fuel-burning equipment (25) through gas compressor (24), with the fuel entered (28) Thorough combustion, the high-temperature flue gas generated enters gas turbine (26), drag gas turbine powered generator (29) generating, complete gas turbine unit Boulez to pause circulation, gas turbine (26) high-temperature flue gas (27) of discharging is discharged after the attached heating surface cooling of exhaust heat boiler body (1) and flue (22);
Described high voltage terminal steam Rankine cycle, refers to by exhaust heat boiler body (1) saturated vapour out (2), forms high pressure superheated steam (3-1) through high-pressure superheater (3), sends into high-pressure turbine (4) drive electrical generators (19) generating; High-pressure turbine (4) exhaust steam out condenses into water of condensation (6) at high pressure vapour condenser (5), water of condensation (6) sends into exhaust heat boiler body (1) through high pressure water pump (7), high-pressure feed-water heater (8), exhaust heat boiler body (1) produces saturated vapour (2) again, thus forms high voltage terminal steam Rankine cycle circuit;
Described low voltage terminal steam Rankine cycle, refers to by low pressure evaporator (14) saturated vapour out, forms low-pressure superheated steam (16) through low-pressure superheater (15), sends into low-pressure turbine (17) drive electrical generators (19) generating; Low-pressure turbine (17) exhaust steam out condenses into low voltage terminal water of condensation (9) at low pressure vapour condenser (18), low pressure evaporator (14) is sent into through condensate pump (10), low-pressure feed heater (11), oxygen-eliminating device (12), low pressure feed water pump (13), produce saturated vapour again, thus form low voltage terminal steam Rankine cycle circuit;
The steam condensation side of described high pressure vapour condenser (5) adopts operation under positive pressure mode, and namely high-pressure turbine (4) pressure of exhaust steam of discharging is higher than atmospheric pressure;
High pressure vapour condenser (5) the i.e. low pressure evaporator (14) of low voltage terminal steam Rankine cycle circuit of described high voltage terminal steam Rankine cycle circuit.
2. device according to claim 1, is characterized in that:
Be provided with high voltage terminal Rankine cycle moisturizing loop: the feedwater of the low voltage terminal steam Rankine cycle that oxygen-eliminating device (12) exports fills into boiler body (1) through high voltage terminal small pump (20), high voltage terminal moisturizing pipeline (21).
3., according to the device one of claim 1 to 2 Suo Shu, it is characterized in that:
Described low-pressure feed heater (11) and flue gas adopt separated type heat exchange mode, comprise vaporizer (11-1), condenser (11-2); Vaporizer (11-1) is arranged in fume side, by phase-change working substance with flue gas wall-type heat exchange, phase-change working substance heat absorption produces steam, steam is by the feedwater wall-type heat exchange of condenser (11-2) with the Rankine cycle of low voltage terminal steam, form condensation water is absorbed flue gas again heat generation steam by vaporizer (11-1) after cooling, thus form the inner cyclic process of phase-change working substance.
CN201310029364.8A 2013-01-27 2013-01-27 Brayton-cascade steam Rankine combined cycle power generation system Expired - Fee Related CN103075216B (en)

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