CN202630027U - Device for utilizing smoke waste heat of boiler of thermal generator set - Google Patents

Abstract

The utility model discloses a device for utilizing the smoke waste heat of a boiler of a thermal generator set. The device can be used for remarkably increasing the utilization efficiency of smoke waste heat. The device comprises an air preheater and a smoke high-pressure feed-water heater, wherein a water outlet of the smoke high-pressure feed-water heater is connected with a water inlet of the boiler; smoke inlet ends of the air preheater and the smoke high-pressure feed-water heater are both connected with a smoke outlet end of the boiler; and smoke discharged from the boiler is divided into a first part of smoke and a second part of smoke which respectively flow through the air preheater and the smoke high-pressure feed-water heater. The smoke is subjected to separate flux recovery, so that the whole recovery and utilization rate of the smoke can be increased; meanwhile, high-pressure feed water heated by utilizing the second part of smoke can directly enter the boiler and be used, so that high-pressure extraction steam required by a turbine for heating the feed water is saved, and the energy consumption of the thermal generator set is reduced as a whole.

Description

The device that the thermal power unit boiler fume afterheat utilizes

Technical field

The utility model relates to the thermal cycle field of mechanical technique, particularly relates to the device that a kind of thermal power unit boiler fume afterheat utilizes.

Background technology

Along with the development of energy-conserving and environment-protective product, the thermal efficiency of maximum discharge industries such as boiler improves also intensification gradually.In boiler heat loss, the proportion that power plant's heat loss due to exhaust gas accounts for is very big.Research shows that the every reduction by 10 of exhaust gas temperature is spent to 15 degree, and the thermal efficiency of boiler just can improve 1%.

At present; Though existing fume afterheat has obtained some utilizations; But still have the very big space that utilizes: along with the flue gas desulfurization and denitrification continuous advancement in technology, flue gas acid dew point has dropped to about 90 ℃, and the exhaust gas temperature operated by rotary motion of large-scale unit is at 120 ~ 140 ℃; That is to say that also there is very big decline space in exhaust gas temperature.Simultaneously; Overcritical and the exhaust gas temperature ultra supercritical unit boiler generally is higher than its design temperature, like this, is higher than the acid dew point of flue gas far away from the flue-gas temperature of economizer exit entering air preheater; This part heat that has more is not fully utilized, and has increased the heat loss of smoke evacuation.

Cause the higher reason of exhaust gas temperature a lot; Possibly be because there are deviation in Actual combustion ature of coal and predetermined burning coal; Add the pickup capabilities of tube wall not enough; The soot blower of back-end surfaces is arranged unreasonable or is acted on not obviously, causes the heating surface of economizer and/or air preheater less than normal, also just can not well bring into play the effect of fume afterheat utilization.

According to present main flow viewpoint, can solve the problems referred to above through following two approach:

The first, the heat transfer area of increase air preheater.The flow area of flue gas in air preheater increases, and flue gas and air reverse flow just can be carried out heat exchange fully when air preheater, effectively improves the not enough problem of fume afterheat heat release.Yet; The heat transfer area of air preheater be not to be the bigger the better: along with the reduction of exhaust gas temperature; The temperature difference of air and flue gas constantly reduces; Air preheater utilizes effect more and more not obvious to fume afterheat, and is a lot of even the heat transfer area of air preheater increases, and flue-gas temperature reduces amplitude can great changes have taken place yet; When economizer bank wall temperature lower when exhaust gas temperature, air preheater is lower than flue gas acid dew point, can produce cold end corrosion, reduce the service life of air preheater, and every separated one or two years or even half a year will be changed; Before this thinking of heat transfer area of continuation optimization air preheater obviously will cause fume afterheat utilization ratio secular stagnation not.

The second, suitably increase the heating surface of economizer.Adopt the low-pressure coal saver of big heating surface can improve feed temperature to a certain extent, strengthen the fume afterheat utilization; But because the flue gas quality that participation is conducted heat is not high, the heat-transfer effect of this device is limited.

Therefore, according to existing main flow thinking, the efficient of fume afterheat utilization has been difficult to than quantum jump; Wanting to improve the fume afterheat utilization ratio must look for another way.How effectively to improve the fume afterheat utilization ratio, be the present technical issues that need to address of those skilled in the art.

The utility model content

The purpose of the utility model provides the device that a kind of thermal power unit boiler fume afterheat utilizes, and this device can significantly improve the efficient that fume afterheat utilizes.

For solving the problems of the technologies described above; The device that the utility model provides a kind of thermal power unit boiler fume afterheat to utilize; Comprise air preheater and flue gas high-pressure feed-water heater; The delivery port of said flue gas high-pressure feed-water heater links to each other with the water inlet of boiler; The gas approach end of said air preheater and flue gas high-pressure feed-water heater all links to each other with the smoke outlet of said boiler, and the flue gas of discharging from said boiler is divided into first's flue gas and second portion flue gas, said first flue gas and second portion flue gas flow through respectively said air preheater and flue gas high-pressure feed-water heater.

The flue gas that produces in the boiler is divided into first's flue gas and second portion flue gas in the process of discharging; First's flue gas carries out last preheating through air preheater to the air of sending into boiler; The second portion flue gas heats high-pressure feed water through the flue gas high-pressure feed-water heater, and the high-pressure feed water after the heating can directly get in the boiler and use.Through above-mentioned processing, most of heat that first's flue gas and second portion flue gas include all is recovered and has utilized, and can directly send into boiler through the air after first's flue gas heating and use; The second portion flue gas heats high-pressure feed water fully; Feedwater after the heating can have been satisfied the needs of boiler; Adopt the bleed burden of heated feed water of turbine high-pressure thereby shared, also just having saved the required high pressure of steam turbine to a great extent bleeds energy-conserving and environment-protective more.

Preferably; Also comprise the flue gas heat exchange device and the air heat exchanger that interconnect and can carry out the heat transmission; The gas approach end of said flue gas heat exchange device links to each other with the smoke outlet of said air preheater with the flue gas high-pressure feed-water heater respectively, and the air outlet slit end of said air heat exchanger links to each other with the air intlet end of said air preheater.

Still remain on higher level through the first's flue gas after flue gas high-pressure feed-water heater and the air preheater processing and the cigarette temperature of second portion flue gas; Connect the flue gas heat exchange device at the two smoke outlet; With remaining few part heat absorption; And then the after-heat that absorbs passed to air heat exchanger; Air heat exchanger utilizes this part heat that the air of sending into boiler is carried out preliminary preheating, and the air after the preliminary preheating is just sent into air preheater and carried out preheating, has alleviated the burden of air preheater.Through after the above multiple processing, the heat of flue gas has obtained sufficient recovery, and flue gas waste heat recovery efficient significantly improves, the not enough problem of flue gas thermal discharge that the flue gas shunting of its entrance point causes when also having solved simple employing air preheater simultaneously; Secondly, flue gas heat exchange device and air heat exchanger relatively simple for structure, both heating surfaces are all adjusted than being easier to, and can effectively avoid the etching problem of heat exchanger through adjusting heating surface.

Preferably, said flue gas heat exchange device absorbs fume afterheat and it is passed to said air heat exchanger through heat transfer medium.

Preferably, also be provided with the circulating pump that power is provided for said heat transfer medium between said flue gas heat exchange device and the air heat exchanger.

Preferably, said boiler further is connected with and is used to control what controller of said first flue gas and second portion flue gas.

Preferably; Said controller has comparator; Said comparator is used for relatively sending into the actual temperature and the predetermined temperature of the air of boiler, if be higher than predetermined temperature, and the amount of then said controller control reducing said first flue gas; If be lower than predetermined temperature, then said controller control increases the amount of said first flue gas.

Be higher than predetermined temperature if send into the actual temperature of the air of boiler; Then controller is controlled the amount that reduces first's flue gas; Otherwise then increase the amount of first's flue gas; According to what of adjustment two parts flue gas of the height real-time of the air themperature of sending into boiler, and then the actual temperature that reaches the air of sending into boiler meets combustion requirements (promptly equating with predetermined temperature perhaps to remain in the fluctuating range of permission).

Description of drawings

The method for using flow process frame diagram of device in a kind of specific embodiment that Fig. 1 provides the thermal power unit boiler fume afterheat to utilize for the utility model;

The structural representation of device in a kind of specific embodiment that Fig. 2 provides the thermal power unit boiler fume afterheat to utilize for the utility model.

The specific embodiment

The core of the utility model provides a kind of thermal power unit boiler fume afterheat use device, and this device is the recovery utilization rate of fume afterheat significantly.In order to make those skilled in the art person understand the utility model scheme better, the utility model is done further to specify below in conjunction with the accompanying drawing and the specific embodiment.

Please refer to Fig. 1, the method for using flow process frame diagram of device in a kind of specific embodiment that Fig. 1 provides the thermal power unit boiler fume afterheat to utilize for the utility model.

In a kind of specific embodiment, the method for using of the device of the thermal power unit boiler fume afterheat utilization that the utility model provided comprises following three steps:

Step S11: the flue gas shunting that will discharge in the boiler becomes first's flue gas and second portion flue gas, can adopt multiple mode of the prior art to realize the shunting of flue gas; For example, can be directly at two pipelines of smoke outlet connection of boiler, flue gas also can connect a current divider at the smoke outlet of boiler with regard to the two parts that are divided into of nature, shunt processing to flue gas;

Step S12: the shunting back forms two parts flue gas, i.e. first's flue gas and second portion flue gas;

Step S14: utilize first's flue gas that the air of sending into boiler is carried out preheating, the second portion flue gas is used to add the high-pressure feed water of Hot gas turbine;

Step S152: the high-pressure feed water that heating is accomplished can satisfy the demand of boiler; Can directly import boiler uses; This part high-pressure feed water imports the female pipe of water delivery of turbine high-pressure feedwater again, gets into boiler then together, also can get into boiler through pipeline separately.

Need to prove; Only relate to above-mentioned four steps in the present embodiment; Shown in Fig. 1 is the detailed process frame diagram of a more preferred embodiment, and other step only is the concrete executory a kind of situation of present embodiment among Fig. 1, and the scope of present embodiment is not limited thereto.

The heat that contains owing to the flue gas of in boiler, discharging is very high; If whole strand of flue gas carried out recycled in its entirety; Be easy to produce problem such as heat exchange is insufficient; The device that the utility model provided is shunted this strand flue gas, reclaims the heat of every partial fume then respectively, effectively raises the efficient of heat exchange; And; The second portion fume centralized is used for the heating high-pressure feedwater; Can directly high pressure be added the temperature that water is heated to the boiler needs, this part feedwater after the heating is directly supplied with to boiler and is used, and has practiced thrift the high pressure extraction that steam turbine needs to a great extent; The high pressure extraction of saving can continue acting in Steam Turbine, improved the utilization rate of fired power generating unit on the whole.

Can the device of fume afterheat utilization mentioned above further be improved.

In the another kind of specific embodiment, can also comprise that after said step S14 step S151 is to step S18.

Step S151: mix to the first's flue gas after the air preheat with to the second portion flue gas after the water under high pressure feedwater heating, form mixed flue gas;

Step S16: adopt heat transfer medium to absorb the after-heat of mixed flue gas, the heat transfer medium kind here is a lot, can be normal temperature or the gas that is lower than normal temperature or liquid etc., for example, can be conduction oil, also can be water etc.;

Step S17: the heat that utilizes heat transfer medium to absorb carries out preliminary preheating to the air of sending into boiler, and the air after this preliminary preheating utilizes first's flue gas of just having discharged from boiler to carry out preheating again, to improve the flue gas utilization rate;

Step S18: through after the above-mentioned multiple processing, the temperature of mixed flue gas significantly reduces, and discharges to the outside then.

It is as herein described that the air of sending into boiler is carried out last preheating is corresponding each other with preliminary preheating, because the flue gas heat of just having discharged in the boiler is than higher, and can be with air heat to higher temperature; Therefore; The flue gas of just from boiler, having discharged carries out last waste heat to air, and satisfying the burning demand of air, and the flue gas heat content after handling is lower; Can only accomplish air preheat, just so-called preliminary preheating than low degree.Obviously, the flow direction of flue gas and air is opposite, can compare sufficient heat exchange like this.

In the third specific embodiment, also comprise step S13 after the step S12 of the utility model, before the step S14: the actual temperature and predetermined temperature comparison that will send into the air of boiler.

If the actual temperature that result relatively shows air is greater than predetermined temperature, execution in step S131 then: reduce the amount of first's flue gas, come back to the amount of confirming two parts flue gas among the step S12, show that up to result relatively both temperature are identical or close; If less than predetermined temperature; Execution in step S132 then: the corresponding amount that increases first's flue gas when flue gas shunting; The adjustment back forms two parts flue gas of ratio new among the step S12; Carry out so repeatedly, show that up to comparative result both temperature are identical or close, just so-called actual temperature equals predetermined temperature in the diagram.

Need to prove; The utility model and do not require the actual temperature of the air of sending into boiler and predetermined temperature identical; Can keep certain temperature difference between the two, but this temperature difference must keep within the specific limits the just above-mentioned close level of both temperature.Said certain limit is carried out concrete regulation according to the model difference of boiler, and concrete setting is repeated no more please with reference to prior art here.

Certainly, for realizing said temperature process relatively, the measurement component of air themperature can be set in boiler; For example can adopt thermometer etc. to measure; Boiler can also be connected with control assembly, stores the predetermined temperature value of air in this control assembly, and measurement component passes to control assembly with detected air themperature; Control assembly compares the actual temperature and the predetermined temperature of air, accomplishes corresponding operation then.

The shunting mode of first's flue gas and second portion flue gas is various, can connect two pipelines at the exhanst gas outlet of boiler, and the control that valve is realized exhaust gas volumn is set on each pipeline then; Also can special current divider be set at the smoke outlet of boiler, play the effect of shunting and control exhaust gas volumn.

The amount of first's flue gas and second portion flue gas can be adjusted according to the purposes of two parts flue gas, and generally speaking, the amount of second portion flue gas accounts for 5% ~ 20% of whole flue gases.

Please refer to Fig. 2, the structural representation of device in a kind of specific embodiment that Fig. 2 provides the thermal power unit boiler fume afterheat to utilize for the utility model.

In Fig. 2, solid line is represented water, and dotted line is represented steam, and flue gas is represented in the single-point line, and air is represented in double dot dash line.

The device that the utility model also provides a kind of fume afterheat to utilize; Comprise air preheater 2 and flue gas high-pressure feed-water heater 4; Flue gas high-pressure feed-water heater 4 is equipped with the gas approach end with air preheater 2, and both gas approach ends all link to each other with the smoke outlet of boiler 1.That is to say; The flue gas of discharging in the boiler is divided into two parts; Be the first's flue gas and the second revenge case flue gas, first's flue gas and second portion flue gas flow through respectively air preheater 2 and flue gas high-pressure feed-water heater 4 are accomplished the heating to air and high-pressure feed water; Because the delivery port of flue gas high-pressure feed-water heater 4 is connected with the water inlet of boiler 1, the high-pressure feed water after the heating can directly get into boiler and use.

Through above-mentioned processing, most of heat that first's flue gas and second portion flue gas include all is recovered and has utilized, and can directly send into boiler through the air after first's flue gas heating and use; The second portion flue gas heats high-pressure feed water fully; Feedwater after the heating can have been satisfied the needs of boiler; Adopt the bleed burden of heated feed water of turbine high-pressure thereby shared, also just having saved the required high pressure of steam turbine to a great extent bleeds energy-conserving and environment-protective more.

In the another kind of specific embodiment; The utility model also is provided with flue gas heat exchange device 5 and air heat exchanger 3; The gas approach end of the smoke outlet of flue gas high-pressure feed-water heater 4 and flue gas heat exchange device 5 is connected; The smoke outlet of air preheater 2 also links to each other with the gas approach end of flue gas heat exchange device 5, and promptly first's flue gas and second portion flue gas carry out recycle once more through flue gas heat exchange device 5 after handling through air preheater 2 and flue gas high-pressure feed-water heater 4 respectively again; The heat that flue gas heat exchange device 5 absorbs can pass to air heat exchanger 3, and air heat exchanger 3 utilizes this part heat that the air of sending into boiler 1 is carried out preliminary preheating; Because the air outlet slit end of air heat exchanger 3 links to each other with the air intlet end of air preheater 2, the air after the preliminary preheating can pass through air preheater 2 and further heat, and satisfies the needs of boiler 1 at last, sends in the boiler 1 and uses.

Wherein, can in pipeline, fully mix the formation mixed flue gas from first's flue gas of air preheater 2 outflows with from the flue gas that flue gas high-pressure feed-water heater 4 flows out, and then the unified flue gas heat exchange device 5 that gets into, help to improve the efficient of heat exchange like this.Certainly, first's flue gas after the processing and second portion flue gas also can flow into flue gas heat exchange device 5 respectively and carry out heat exchange.

In the third specific embodiment; Flue gas heat exchange device 5 can be through the heat transmission between heat transfer medium realization and the air heat exchanger 3; Realize the heat transmission of flue gas to heat transfer medium through the countercurrent heat-transfer principle in the flue gas heat exchange device 5, heat transfer medium absorbs and stores from the waste heat of mixed flue gas and with heat; Heat transfer medium flows is to air heat exchanger 3 then, and heat transfer medium is realized the preliminary preheating to air with the heat transferred air that stores in air heat exchanger 3.Wherein heat transfer medium can be that conduction oil or water etc. can absorb the liquid that passes to heat or can realize the gas that energy transmits.

For realizing heat transfer medium flowing between flue gas heat exchange device 5 and air heat exchanger 3 smoothly, circulating pump 6 can be set.Heat transfer medium generally can be warmed up to 80-100 ℃ after in flue gas heat exchange device 5, absorbing heat; Heat transfer medium after the intensification gets into liquid reserve tank 7; And then boost through circulating pump 6 and to get into air heat exchanger 3; Temperature can reduce after heat transfer medium is accomplished the heat conversion, and the heat transfer medium after the cooling circulates once more and gets into flue gas heat exchange device 5 absorption heats, so realizes the absorption and the transmission of heat repeatedly.

The air intlet end of air heat exchanger 3 links to each other with pressure fan, and pressure fan is sent the air under the normal temperature into air heat exchanger 3, and air will absorb the heat of heat transfer medium.Generally speaking, air can tentatively be preheating to 40-70 ℃, and the air of accomplishing preliminary preheating gets into air preheater 2 again and carries out last preheating.Because the heat of the heat transfer medium in the air heat exchanger 3 is absorbed, the temperature of heat transfer medium generally can drop to 60-80 ℃, and cooled heat transfer medium turns back to and continues to absorb heat in the flue gas heat exchange device 5, gets into the next round thermal cycle.Temperature through the mixed flue gas after 5 processing of flue gas heat exchange device generally can drop to 90-120 ℃, and the flue gas of this moment can directly get into chimney through flue and discharge.

If the air themperature of the air outlet slit end of air preheater 2 is lower than the requirement (be the predetermined temperature of air) of boiler to air themperature; Then strengthen the fluid flow of circulating pump 6; Accelerate the heat transfer rate of heat transfer medium, let air is continual to carry out heat exchange with heat transfer medium high temperature, thereby improve the temperature after the preliminary preheating of air; Then the air of preliminary preheating is sent into air preheater 2 and heat at last, to satisfy the requirement of boiler air themperature; Otherwise, then reducing the fluid flow of circulating pump 6, the speed of slow down heat transfer medium and air heat exchange reduces the flow and the flow velocity of heat transfer medium, reduces the temperature after the preliminary preheating of air.

As everyone knows, the wall pipe temperature of flue gas heat exchange device 5 can not be low excessively, if the temperature of wall pipe is lower than the dew point of flue gas, cold end corrosion will take place flue gas heat exchange device 5, and therefore, the exhaust gas temperature of flue gas heat exchange device 5 will remain on certain limit.If the exhaust gas temperature of flue gas heat exchange device 5 is lower than setting value; The amount (promptly reducing to get into the exhaust gas volumn of flue gas high-pressure feed-water heater 4) that then reduces the second portion flue gas lets more flue gas shunting give first's flue gas, thereby improves the mixing temperature of first's flue gas and second portion flue gas; If be higher than setting value, then increase the amount of second portion flue gas.

Why above-mentioned adjustment can realize that the adjustment of temperature of mixed flue gas is main because the heat conducting amount that the second portion flue gas produces is more than first's flue gas:

At first, the amount of first's flue gas is bigger than the amount of second portion flue gas, and therefore, the contained total amount of heat of first's flue gas is more than the second portion flue gas, and the second portion flue gas generally only accounts for the 5%-20% of whole flue gases; Secondly; The heat of second portion flue gas will be heated to high-pressure feed water and satisfy the temperature requirements of boiler to feedwater; Feedwater generally will be heated to 230-300 ℃ from 150-190 ℃; The heat transmission that produces in this process is relatively many, and the flue gas of first gets into the air that 2 pairs in air preheater carries out preheating and carries out post bake, is equivalent to the heat transmission that compares less with many heat realizations.Therefore, there is certain difference in the heat transmission of first's flue gas and second portion flue gas, and the second portion flue gas is relatively low with the temperature that feedwater is carried out after heat transmits, and the amount that reduces the second portion flue gas just can increase the temperature of mixed flue gas on the whole.

Need to prove, when the amount of second portion flue gas changes, also will adjust the amount of the feedwater that the second portion flue gas heated accordingly, when the amount of second portion flue gas reduced, the amount of feedwater was also wanted corresponding reducing, and vice versa.Generally speaking, the amount of the feedwater of flue gas high-pressure feed-water heater 4 heating accounts for the 2%-20% of steam turbine confluent.

Flue gas in the boiler forms first's flue gas and second portion flue gas through shunting:

The second portion flue gas at first heats through the high-pressure feed water in flue gas high-pressure feed-water heater 4 pairs of steam turbines, and the high-pressure feed water after the heating directly imports the feed main of boiler, that is to say that the feedwater after the heating can directly satisfy the needs of boiler.Flue gas high-pressure feed-water heater 4 is equivalent to the high-pressure heater of Steam Turbine Regenerative System; The high pressure heating is carried out in the feedwater of 2%-20%; Reduced the amount of drawing gas of high-pressure heater; That part of the drawing gas of saving can be continued acting in steam turbine, also played the effect that improves unit efficiency to a certain extent.

First's flue gas flow direction air preheater 2; Air and the reverse circulation of flue gas are arranged in the air preheater 2 simultaneously; According to countercurrent heat-transfer; Air preheater 2 utilizes first's flue gas that the air of sending into boiler is carried out last preheating, generally with air preheat to 250-330 ℃, make air satisfy the burning needs and then send into boiler; At this moment, the abundant release heat of first's flue gas in the air preheater 2, the higher and problem that can't make full use of of the cigarette temperature that has solved air preheater 2 gas approach ends.

First's flue gas flows out the back from air preheater 2 to be mixed with the second portion flue gas that from flue gas high-pressure feed-water heater 4, flows out; Flow into flue gas heat exchange device 5 then; Heat transfer medium in the flue gas heat exchange device 5 absorbs fume afterheat; Flow to air heat exchanger 3 then, heat transfer medium is with the heat transferred air.Generally speaking, through preliminary preheating, air can be preheating to 40-70 ℃ from atmospheric temperature, and the air after the preliminary preheating is sent into air preheater 2, and this air just air preheater 2 utilizes first's flue gas to carry out the air of last preheating.

Through said process, first's flue gas and second portion flue gas are all through twice recycling, and the overwhelming majority of flue gas heat all is recovered utilization, and the flue gas utilization rate is improved; Secondly, the air that boiler combustion needs has also passed through twice preheating, the too high problem of air preheater load when having avoided adopting a preheating; At last, the second portion flue gas that distributes has been saved the energy of steam turbine to a great extent, has played effect preferably.

Be the further amount of control first's flue gas and second portion flue gas, boiler 1 can connect controller is set, controller be used to control above-mentioned first flue gas and second portion flue gas how much.

Be to realize the control purpose of controller, controller generally has comparator, and this comparator is used for relatively sending into the actual temperature and the predetermined temperature of the air of boiler; Generally store the predetermined temperature that pre-set air burning need be satisfied in the controller; When air was sent into boiler, this air had an actual temperature, and comparator is with the actual temperature and the predetermined temperature contrast of air; If actual temperature is higher than predetermined temperature; Then controller control reduces the amount of first's flue gas, if be lower than predetermined temperature, then controller control increases the amount of first's flue gas; If just in time equal predetermined temperature or both temperature differences in allowed limits, then controller control is kept the amount of first's flue gas or is carried out a spot of adjustment.

Generally, first's flue gas accounts for 80%～95% of whole flue gases, and the second portion flue gas accounts for 5% ~ 20% of whole flue gases.Adopt aforementioned proportion that flue gas is shunted and help two-part flue gas and can both carry out heat exchange preferably, efficiency of utilization is higher.

More than the device of the fume afterheat utilization that the utility model provided has been carried out detailed introduction.Used concrete example among this paper the principle and the embodiment of the utility model are set forth, the explanation of above embodiment just is used to help to understand the device and the core concept thereof of the utility model.Should be understood that; For those skilled in the art; Under the prerequisite that does not break away from the utility model principle, can also carry out some improvement and modification to the utility model, these improvement and modification also fall in the protection domain of the utility model claim.

Claims (6)

1. the device that utilizes of a thermal power unit boiler fume afterheat; It is characterized in that; Comprise air preheater and flue gas high-pressure feed-water heater; The delivery port of said flue gas high-pressure feed-water heater links to each other with the water inlet of boiler; The gas approach end of said air preheater and flue gas high-pressure feed-water heater all links to each other with the smoke outlet of said boiler, and the flue gas of discharging from said boiler is divided into first's flue gas and second portion flue gas, said first flue gas and second portion flue gas flow through respectively said air preheater and flue gas high-pressure feed-water heater.

2. device as claimed in claim 1; It is characterized in that; Also comprise the flue gas heat exchange device and the air heat exchanger that interconnect and can carry out the heat transmission; The gas approach end of said flue gas heat exchange device links to each other with the smoke outlet of said air preheater with the flue gas high-pressure feed-water heater respectively, and the air outlet slit end of said air heat exchanger links to each other with the air intlet end of said air preheater.

3. device as claimed in claim 2 is characterized in that, said flue gas heat exchange device absorbs fume afterheat and it is passed to said air heat exchanger through heat transfer medium.

4. device as claimed in claim 3 is characterized in that, also is provided with the circulating pump that power is provided for said heat transfer medium between said flue gas heat exchange device and the air heat exchanger.

5. like each described device of claim 1 to 4, it is characterized in that said boiler further is connected with and is used to control what controller of said first flue gas and second portion flue gas.

6. device as claimed in claim 5; It is characterized in that said controller has comparator, said comparator is used for relatively sending into the actual temperature and the predetermined temperature of the air of boiler; If be higher than predetermined temperature; Then said controller control reduces the amount of said first flue gas, if be lower than predetermined temperature, then said controller control increases the amount of said first flue gas.

Images