CN203744221U - Emission reduction system for smoke and dust of power plant boiler - Google Patents

Abstract

The utility model discloses an emission reduction system for smoke and dust of a power plant boiler. The emission reduction system comprises an air pre-heater, a cryogenic heat exchanger, a dust remover, a draught fan, a desulfurizing tower and a chimney which are sequentially connected to a boiler flue in series in sequence, and further comprises an air heat exchanger and a secondary draught fan which are sequentially connected to the outer side of the boiler flue in series in sequence. The output end of the secondary draught fan is connected with the air side input end of the air pre-heater through the air heat exchanger. The emission reduction system further comprises a first water pump, wherein the heat exchange medium output end of the air heat exchanger is connected to the heat exchange medium input end of the cryogenic heat exchanger through the first water pump, the heat exchange medium output end of a low temperature heat exchanger is connected with the heat exchange medium input end of the air heat exchanger, and the temperature of the outlet of the cryogenic heat exchanger ranges from 80 DEG C to 100 DEG C. According to the emission reduction system, the smoke discharge temperature of the boiler is lowered to the temperature around the smoke acid dew point, and therefore the dust removal efficiency of the dust remover is effectively improved; meanwhile, the aim of recycling waste heat of discharged smoke to the maximum degree is achieved.

Description

A kind of emission-reducing system of boiler of power plant exhaust gas dust

Technical field

The utility model relates to a kind of emission-reducing system of boiler of power plant exhaust gas dust.

Background technology

In recent years, climatic deterioration problem receives the increasing concern of society, and in minimizing air, dust content is increasingly important.The thermal power plant in the main city of 47 key cities that 2013 No. 14 bulletins of Chinese Ministry of Environmental Protection require, need meet special emission limit 20mg/m in the soot emissions of chimney entrance after dust removal installation and desulphurization system transformation ³.Meanwhile, because demand for energy increases, coal shortage brings series of problems to power industry.The raising energy utilization rate of adopting an effective measure, reducing cost of electricity-generating has become the common recognition of electricity power enterprise.

At present, the design of boiler unit exhaust gas temperature is mainly that boiler thermal output is lower based on considering Unit Economic exhaust gas temperature, thinking that exhaust gas temperature is higher, but under lower exhaust gas temperature (110 DEG C), can increase the corrosion risk of metal heated of boiler tail.Therefore, in the prior art, the design load of exhaust gas temperature is substantially more than flue gas acid dew point, and a little more than flue gas acid dew point." Principles of Boiler (second edition) " the 223rd page of publishing referring to China Electric Power Publishing House, from table 12-1, the current design for exhaust gas temperature is generally more than 110 DEG C (higher than flue gas acid dew point), reaching higher boiler thermal output when, prevent metal heated and the corrosion of equipment in back-end ductwork.

In recent years, although boiler exhaust gas heat recovery technology, at development, is subject to the impact of economic exhaust gas temperature, the range of decrease is limited, in China's active service fired power generating unit, the exhaust gas temperature of boiler, about 130 DEG C-160 DEG C, substantially all exceedes 110 DEG C of intrinsic economic exhaust gas temperatures.In the prior art, disclosing one utilizes the associating of smoke discharging residual heat heating air preheater entrance cold air-low-pressure coal saver to utilize step by step system, wherein, high-temperature heat-exchanging is used for heating main condensate, cryogenic heat exchanger is used for heating Secondary Air, applies after this scheme in certain power plant's 600MW boiler improvement, and cryogenic heat exchanger outlet temperature is down to 130 DEG C, compared with 160 DEG C of annual exhaust gas temperatures before transformation, 30 DEG C are reduced.Although apply after this scheme, exhaust gas temperature decreases drastically, 130 DEG C of exhaust gas temperatures still maintain higher level, have only reached near 139 DEG C of former design parameters of unit.

Efficiency of dust collection and the exhaust gas temperature of deduster are in close relations, and at exhaust gas temperature, lower than below 150 DEG C time, flue dust raises along with the rising of exhaust gas temperature than resistance, and high flue dust can reduce the efficiency of dust collection of deduster than resistance.In a word, prior art is arranged on exhaust gas temperature more than 110 DEG C, although overcome the problem of flue gas acid dew point corrosion, but weak point is: not yet can utilize cmpletely on the one hand smoke discharging residual heat, on the other hand, at this temperature, flue dust is higher than resistance, the efficiency of dust collection of deduster is low, and smoke evacuation dust concentration is at 25mg/Nm ³above.

Therefore, how to design a system and can make full use of smoke discharging residual heat; Can improve to greatest extent again the efficiency of dust collection of deduster, make unit dust emission concentration reach national requirements for environmental protection and can long-term safety stably move the research and development blind spot that is still those skilled in the art.

The utility model people is the long-term practical exploration of process in project, overcome device structure large, the complicated all difficulties that wait of pipeline installation and debugging, overcome prior art and thought that exhaust gas temperature need be arranged on technology prejudice more than flue gas acid dew point, by the utilization of smoke discharging residual heat is combined effectively with the efficiency of dust collection of deduster, found out the more excellent scheme that a set of boiler afterheat reclaims energy-saving and emission-reduction, this case produces thus.

Utility model content

Technical problem underlying to be solved in the utility model is to provide a kind of emission-reducing system of boiler of power plant exhaust gas dust, be intended to overcome the deficiencies in the prior art, deduster inlet flue gas temperature is down near flue gas acid dew point, deduster dust specific resistance is declined, to improve deduster efficiency of dust collection; Meanwhile, realize the object that reclaims to greatest extent smoke discharging residual heat.

For solving the problems of the technologies described above, the utility model provides a kind of emission-reducing system of boiler of power plant exhaust gas dust, it is characterized in that: comprise the air preheater, cryogenic heat exchanger, deduster, blower fan, desulfurizing tower and the chimney that are serially connected with successively boiler flue; And comprise the air heat exchanger and the overfire air fan that are serially connected with successively outside boiler flue, described overfire air fan output connects the air side input of described air preheater through described air heat exchanger, native system also comprises the first water pump, the heat transferring medium output of described air heat exchanger connects the heat transferring medium input of described cryogenic heat exchanger through described the first water pump, the heat transferring medium output of described cryogenic heat exchanger connects the heat transferring medium input of described air heat exchanger;

Native system also comprises high-temperature heat-exchanging, the second water pump and low-pressure heater, described high-temperature heat-exchanging is located between described air preheater and cryogenic heat exchanger, described low-pressure heater is serially connected with in the main condensate pipeline of steam turbine, the input of described low-pressure heater connects the heat transferring medium input of described high-temperature heat-exchanging through described the second water pump, the heat transferring medium output of described high-temperature heat-exchanging connects the output of described low-pressure heater.

Further, described cryogenic heat exchanger is membrane heat exchanger, comprises heat exchange fin and fluid hose; Be coated with Inorganic and Nonmetallic Coating and acidproof polymeric coating layer; Described fluid hose is located at the both sides of described heat exchange fin.

Further, described heat exchange fin comprises base plate, top board and two pipes; Described two pipes are arranged in parallel and have vertically an elongated slot, and described base plate and top board positioned opposite both sides are connected respectively base and the top margin of described two pipe elongated slots, and the diameter of two pipes of described heat exchange fin is greater than the diameter of described fluid hose.

Further, described base plate and top board are arranged in parallel or are splayed and arrange.

Further, at cathode hanger place and the ash bucket place of described deduster, be also respectively equipped with electric heater.

Further, native system also comprises expansion tank, and the output of described expansion tank connects the input of described the first water pump.

Further, described low-pressure heater comprises primary heater, secondary heater, the 3rd heater and the 4th heater of serial connection successively.

Further, native system also comprises recirculation control valve, the first valve, the second valve, the 3rd valve and the 4th valve, described recirculation control valve is serially connected with between the heat transferring medium output of described high-temperature heat-exchanging and the input of the second water pump, described the first valve is connected between described primary heater output and the heat transferring medium output of high-temperature heat-exchanging, described the second valve is connected between described primary heater input and the heat transferring medium output of high-temperature heat-exchanging, described the 3rd valve is connected between described secondary heater input and the second water pump input, described the 4th valve is connected between described the 4th heater input and the second water pump input.

The utility model has adopted after technique scheme, by exhaust gas temperature is dropped to below flue gas acid dew point, by reducing deduster inlet flue gas temperature to flue gas acid dew point, reduce deduster dust specific resistance, effectively improve the efficiency of dust collection of deduster, made chimney breast dust emission concentration be reduced to 15～18mg/Nm ³, reached discharging standards; Meanwhile, at 80-100 DEG C of lower temperature, realize the object that reclaims to greatest extent smoke discharging residual heat, made generating set benefit of saving coal reach 3g/kWh left and right.

Brief description of the drawings

Below in conjunction with drawings and embodiments, the utility model is described in further detail:

Fig. 1 is the emission-reducing system schematic diagram of the utility model boiler of power plant exhaust gas dust;

Fig. 2 is the structural representation of the utility model cryogenic heat exchanger;

Fig. 3 is the schematic diagram that the utility model cryogenic heat exchanger heat exchange fin is parallel construction;

Fig. 4 is that the heat exchange fin of the utility model cryogenic heat exchanger is the schematic diagram of splayed structure;

Fig. 5 is the structural representation of the utility model deduster.

Detailed description of the invention

As shown in Figure 1, the emission-reducing system of the utility model boiler of power plant exhaust gas dust comprises the air preheater 1 that is serially connected with successively boiler flue, cryogenic heat exchanger 3, deduster 13, air-introduced machine 14, booster fan 15, desulfurizing tower 16 and chimney 17 and comprise the air heat exchanger 4 and the overfire air fan 18 that are serially connected with successively outside boiler flue, described overfire air fan 18 outputs connect the air side input of described air preheater 1 through described air heat exchanger 4, native system also comprises the first water pump 7, the heat transferring medium output of described air heat exchanger 4 connects the heat transferring medium input of described cryogenic heat exchanger 3 through described the first water pump 7, the heat transferring medium output of described cryogenic heat exchanger 3 connects the heat transferring medium input of described air heat exchanger 4,

With reference to figure 2-4, described cryogenic heat exchanger 3 is membrane heat exchanger, comprises heat exchange fin 31 and fluid hose 32, is coated with Inorganic and Nonmetallic Coating and acidproof polymeric coating layer; Described fluid hose 32 is located at the both sides of described heat exchange fin 31.

Described heat exchange fin 31 comprises base plate 311, top board 312 and two pipes 313; Described two pipes 313 are arranged in parallel and have vertically elongated slot, described base plate 311 and top board 312 positioned opposite both sides are connected respectively base and the top margin of described two pipe 313 elongated slots, the diameter of two pipes 313 of described heat exchange fin is greater than the diameter of described fluid hose 32, and described base plate 311 and top board 312 are arranged in parallel or are splayed and arrange.

With further reference to Fig. 1, native system also comprises high-temperature heat-exchanging 2, the second water pump 8 and low-pressure heater 5, described high-temperature heat-exchanging 2 is located between described air preheater 1 and cryogenic heat exchanger 3, described low-pressure heater 5 is serially connected with in the main condensate pipeline 9 of steam turbine, the input of described low-pressure heater 5 connects the heat transferring medium input of described high-temperature heat-exchanging 2 through described the second water pump 8, the heat transferring medium output of described high-temperature heat-exchanging 2 connects the output of described low-pressure heater 5.Described low-pressure heater 5 comprises primary heater 51, secondary heater 52, the 3rd heater 53 and the 4th heater 54 of serial connection successively.

Native system also comprises expansion tank 41, and the output of described expansion tank 41 connects the input of described the first water pump 7.

Native system also comprises recirculation control valve 21, the first valve 61, the second valve 62, the 3rd valve 63 and the 4th valve 64, described recirculation control valve 21 is serially connected with between the heat transferring medium output of described high-temperature heat-exchanging 2 and the input of the second water pump 8, described the first valve 61 is connected between described primary heater 51 outputs and the heat transferring medium output of high-temperature heat-exchanging 2, described the second valve 62 is connected between described primary heater 51 inputs and the heat transferring medium output of high-temperature heat-exchanging 2, described the 3rd valve 63 is connected between described secondary heater 52 inputs and the second water pump 8 inputs, described the 4th valve 64 is connected between described the 4th heater 54 inputs and the second water pump 8 inputs.

With reference to figure 5, cathode hanger 131 places of described deduster 13 and ash bucket 132 places, be also respectively equipped with electric heater 133, low to prevent cigarette temperature drop, causes dust deposit, and then cause stifled grey phenomenon.

A control method for the emission-reducing system of boiler of power plant exhaust gas dust, comprises following step:

1), cryogenic heat exchanger and air heat exchanger control flow:

(1) judge whether expansion tank liquid level meets startup requirement;

(2) start the first water pump;

(3) judge that whether deduster inlet flue gas temperature value is stable;

(4) drop into the first water pump and automatically regulate, make deduster inlet flue gas temperature be controlled at 80-100 DEG C;

2), high-temperature heat-exchanging control flow:

(1) judge the water temperature situation that primary heater, secondary heater, the 3rd heater and the 4th heater are imported and exported;

(2) open the first or second valve of native system;

(3) open the 3rd or the 4th valve of native system;

(4) start the second water pump;

(5) judge that whether high-temperature heat-exchanging outlet cigarette temperature value is stable;

(6) drop into the second water pump and automatically regulate, make high-temperature heat-exchanging outlet fibre selection higher than deduster inlet flue gas temperature 20-25 DEG C;

(7) drop into recirculation control valve and automatically regulate, high-temperature heat-exchanging inlet water temperature is controlled at higher than water dew point 20-25 DEG C.

In native system, further adopt high-temperature heat-exchanging 2 and to be serially connected with low-pressure heater 5 in steam turbine condensate system 9 in parallel, low-pressure heater 5 can adopt four heaters to be in series, the second water pump 8 is set in pipeline, be used for overcoming equipment and the resistance of ducting, adjust flux, in order to control exhanst gas outlet temperature.Four valves that arrange are respectively two inlet valves and two backwater valves, for according to the flooding parameter of different regulating working conditions high-temperature heat-exchangings and backwater position; Recirculation control valve 21 is set on water return pipeline, for regulating diversion pipeline fluid temperature (F.T.), avoids pipeline wall temperature too low.Boiler smoke from air preheater 1 out, after high-temperature heat-exchanging 2, is controlled by the second water pump 8, and flue-gas temperature is down to above 15～20 DEG C of left and right of acid dew point; Flue gas after temperature drop enters cryogenic heat exchanger 3, controls by the first water pump 7, and flue-gas temperature is down near flue gas acid dew point, and flue gas enters deduster 13.The heat that high-temperature heat-exchanging 2 absorbs simultaneously coordinates the condensate water for adding Hot gas turbine with primary heater 51 and secondary heater 52, cryogenic heat exchanger 3 is for controlling the input gas temperature of deduster 13, the heat absorbing for adding the air of hot-air heat exchanger 4 imports, reaches the object of alleviating air preheater 1 cold junction cold end corrosion by hydrophily pipeline.

Base plate 311, top board 312 and two pipes 313 of the heat exchange fin 31 in this cryogenic heat exchanger 3 form the special pipe that cross section is dumb-bell shape, add band steel structure than the light pipe of traditional membrane type heat exchanger plates, increase heat exchange area, strengthen flue gas 31 stream between fluid hose 32 and heat exchange fin, reached the object of enhanced heat exchange; The dumbbell-shaped section of described heat exchange fin 31 has good flexibility simultaneously, carries out in high-temperature heat treatment process at heat exchange fin 31, can effectively reduce high temperature deformation, improves the quality of heat exchange fin 31; Described heat exchange fin 31 can be realized batch production by mould, reduces cost of manufacture; The membrane type heat exchanger plates of described temperature heat exchanger 3 adopts some above-mentioned heat exchange fins 31 to form, and some fluid hoses 32 are located between some heat exchange fins 31 and according to this and are communicated with, thereby improves the heat transfer efficiency of whole cryogenic heat exchanger 3.The diameter of the pipe 313 of described heat exchange fin 31 both sides is greater than the diameter of fluid hose 32, has avoided directly washing away of high ash-laden gas fluid pipe 32, can effectively prevent dust stratification.Meanwhile, the surface of described fluid hose 32 and heat exchange fin 31 is coated with inorganic coating and macromolecule acid-proof coating, and the acid resistance of cryogenic heat exchanger 3 is strengthened greatly, can overcome well cold end corrosion, and making flue-gas temperature be down to acid dew point becomes possibility below.

In native system, the heat transferring medium of cryogenic heat exchanger 3 and air heat exchanger 4, by the hydrophily pipeline composition circulatory system, arranges the first water pump 7, for overcoming equipment and the resistance of ducting, adjust flux, controls flue-gas temperature; The circulatory system arranges expansion tank 41, and described expansion tank 41 is connected to the entrance of the first water pump 7 by single tube, for level pressure before pump, accommodate and the breathing amount of bucking-out system heat transferring medium.

On the one hand, cryogenic heat exchanger 3 is for regulating the flue-gas temperature that enters deduster, and flue-gas temperature significantly reduces, and the flue gas volume flow in deduster 13 and downstream thereof reduces, and reduces the energy consumption of deduster 13 and air-introduced machine 14; By flue-gas temperature control, dust specific resistance in flue gas is optimized simultaneously, improves the efficiency of dust collection of deduster 13, thereby reduce dust emission, and then make chimney breast dust emission concentration be reduced to 15～18mg/Nm ³, reach discharging standards, and traditional flue gas is recycled the chimney breast dust of scheme at 25mg/Nm ³above, therefore native system has obvious reduction of discharging effect.

On the other hand, it enters the air of boiler by air heat exchanger 4 heating, improve fume afterheat quality, improve fume afterheat utilization ratio, make generating set benefit of saving coal reach 3g/kWh left and right, and traditional flue gas is recycled the benefit of saving coal of scheme generally in 2.0g/kWh left and right, therefore native system has significant waste heat recovery and energy-saving benefit.

In native system, high-temperature heat-exchanging 2 utilizes smoke discharging residual heat to add Hot gas turbine condensate water, controls exit gas temperature, squeezes the low-pressure heater that the quality of drawing gas is higher and draws gas, and reduces the consumption of standard coal for power generation of generating set hear rate and generating set.In the prior art, the low-pressure heater that adds Hot gas turbine condensate water for drawing gas is typically provided with multiple, comprise that the condensate water input that is serially connected with successively steam turbine is to the 4th heater 54 of output, the 3rd heater 53, secondary heater 52 and primary heater 51, condensate water input and output are condenser output and the oxygen-eliminating device input of the condensate system of steam turbine, conventionally the condensate water that high-temperature heat-exchanging utilizes smoke discharging residual heat to heat is by the more inferior condensate water of the 3rd heater 53 and the 4th heater 54, and can not heat by the condensate water of the higher quality of primary heater 51 and secondary heater 52, so smoke discharging residual heat utilization rate is low, native system enters the air of air preheater 1 by air heat exchanger 4 heating, make boiler flue-gas temperature out higher, therefore can heat by high-temperature heat-exchanging 2 condensate water of the draw gas higher primary heater 51 of quality and secondary heater 52.This high-temperature heat-exchanging 2 is in high ash-laden gas environment, and dust stratification and wearing and tearing need be taken measures to prevent in the aspects such as its material, technique, design.

In the utility model cryogenic heat exchanger 3 export fibre selection can according to high-temperature heat-exchanging 2 export cigarette temperature variation carry out preconditioning; High-temperature heat-exchanging 2 and cryogenic heat exchanger 3 belong to two independently systems, and in the time of high-temperature heat-exchanging 2 fault, cryogenic heat exchanger 3 can continue operation; Or when cryogenic heat exchanger 3 or air heat exchanger 4 fault, high-temperature heat-exchanging 2 can continue operation, and system has very strong flexibility and adaptability, can under the various operating modes of power plant, move, and have certain economic benefit.

The flue gas heat that air heat exchanger 4 utilizes cryogenic heat exchanger 3 to absorb, add the inlet air of hot-air heat exchanger 4, make the flue-gas temperature exporting through air heat exchanger 4 increase, improve flue gas quality, improve native system flue gas waste heat recovery efficiency, the air themperature that is entered boiler by air preheater 1 rises, and boiler efficiency is improved.Certainly, between booster fan 15 and desulfurizing tower 16, also can establish the second cryogenic heat exchanger, make smog discharge temperature lower (80 DEG C and following), although further reclaimed heat, but correspondingly also can increase the input of equipment, for some energy-conservation less demanding power plant, increase undoubtedly operation cost.The cryogenic heat exchanger 3 that this programme is provided with before deduster, can guarantee that the flue-gas temperature that enters deduster, near acid dew point, is issued to optimum emission reduction effect in this temperature, therefore this programme is being guaranteed under optimum emission reduction effect prerequisite, reduce equipment investment, reduced operation cost.

The above, it is only the utility model preferred embodiment, therefore can not limit according to this scope that the utility model is implemented, the equivalence of doing according to the utility model the scope of the claims and description changes and modifies, and all should still belong in the scope that the utility model contains.

Claims (8)

1. an emission-reducing system for boiler of power plant exhaust gas dust, is characterized in that: comprise the air preheater, cryogenic heat exchanger, deduster, blower fan, desulfurizing tower and the chimney that are serially connected with successively boiler flue; And comprise the air heat exchanger and the overfire air fan that are serially connected with successively outside boiler flue, described overfire air fan output connects the air side input of described air preheater through described air heat exchanger, native system also comprises the first water pump, the heat transferring medium output of described air heat exchanger connects the heat transferring medium input of described cryogenic heat exchanger through described the first water pump, the heat transferring medium output of described cryogenic heat exchanger connects the heat transferring medium input of described air heat exchanger;

Native system also comprises high-temperature heat-exchanging, the second water pump and low-pressure heater, described high-temperature heat-exchanging is located between described air preheater and cryogenic heat exchanger, described low-pressure heater is serially connected with in the main condensate pipeline of steam turbine, the input of described low-pressure heater connects the heat transferring medium input of described high-temperature heat-exchanging through described the second water pump, the heat transferring medium output of described high-temperature heat-exchanging connects the output of described low-pressure heater.

2. the emission-reducing system of a kind of boiler of power plant exhaust gas dust according to claim 1, is characterized in that: described cryogenic heat exchanger is membrane heat exchanger, comprises heat exchange fin and fluid hose; And be coated with Inorganic and Nonmetallic Coating and acidproof polymeric coating layer; Described fluid hose is located at the both sides of described heat exchange fin.

3. the emission-reducing system of a kind of boiler of power plant exhaust gas dust according to claim 2, is characterized in that: described heat exchange fin comprises base plate, top board and two pipes; Described two pipes are arranged in parallel and have vertically an elongated slot, and described base plate and top board positioned opposite both sides are connected respectively base and the top margin of described two pipe elongated slots, and the diameter of two pipes of described heat exchange fin is greater than the diameter of described fluid hose.

4. the emission-reducing system of a kind of boiler of power plant exhaust gas dust according to claim 3, is characterized in that: described base plate and top board are arranged in parallel or are splayed and arrange.

5. the emission-reducing system of a kind of boiler of power plant exhaust gas dust according to claim 1, is characterized in that: at cathode hanger place and the ash bucket place of described deduster, be also respectively equipped with electric heater.

6. the emission-reducing system of a kind of boiler of power plant exhaust gas dust according to claim 1, is characterized in that: native system also comprises expansion tank, and the output of described expansion tank connects the input of described the first water pump.

7. the emission-reducing system of a kind of boiler of power plant exhaust gas dust according to claim 1, is characterized in that: described low-pressure heater comprises primary heater, secondary heater, the 3rd heater and the 4th heater of serial connection successively.

8. the emission-reducing system of a kind of boiler of power plant exhaust gas dust according to claim 7, it is characterized in that: native system also comprises recirculation control valve, the first valve, the second valve, the 3rd valve and the 4th valve, described recirculation control valve is serially connected with between the heat transferring medium output of described high-temperature heat-exchanging and the input of the second water pump, described the first valve is connected between described primary heater output and the heat transferring medium output of high-temperature heat-exchanging, described the second valve is connected between described primary heater input and the heat transferring medium output of high-temperature heat-exchanging, described the 3rd valve is connected between described secondary heater input and the second water pump input, described the 4th valve is connected between described the 4th heater input and the second water pump input.