CN212618218U - Large-capacity circulating fluidized bed boiler - Google Patents

Abstract

The utility model provides a large capacity circulating fluidized bed boiler, including waterwall furnace, cyclone and back cigarette well, waterwall furnace's high temperature exhanst gas outlet is linked together with cyclone's entry, cyclone's solid-state material export is linked together with waterwall furnace's feed back mouth, cyclone's gaseous material export is linked together with the back cigarette well and is used for heating the feedwater, waterwall furnace, cyclone provides soda main circulation return circuit after being connected with the back cigarette well, a serial communication port, soda main circulation return circuit's the heating surface is only including arranging the screen structure in waterwall furnace. The utility model discloses can satisfy large capacity circulating fluidized bed boiler capacity requirement, the design is nimble, and the regulation performance is good, can adapt to the safe and stable operation of different fuel and assurance boiler.

Description

Large-capacity circulating fluidized bed boiler

Technical Field

The utility model relates to a high-efficient ultra supercritical circulating fluidized bed boiler, concretely relates to large capacity circulating fluidized bed boiler's totality is arranged and soda flow design thereof.

Background

The circulating fluidized bed boiler has the characteristics of wide fuel application range, low pollution emission and the like, and is widely applied to various industries. In order to obtain higher energy utilization rate, the design of the circulating fluidized bed boiler continuously develops towards the direction of high capacity and high parameter. In order to meet the requirement, the structural arrangement of the large-capacity circulating fluidized bed boiler and the steam-water flow design thereof are provided.

As shown in figure 1, the structure of the traditional circulating fluidized bed boiler is simplified, and the boiler is of a single-hearth M-shaped structure, and a hearth 1, a cyclone separator 2 and a rear smoke well 3 are arranged in an M shape. The hearth 1 is a membrane wall heating surface structure, a water-cooling screen 5 and a overheating screen 6 can be arranged in the hearth 1, feed water is heated by an economizer 4 '(a primary economizer) and an economizer 4' (a secondary economizer) in a rear smoke well 3 and then flows to the hearth 1 and the water-cooling screen 5 through a steam pocket and a down pipe, and the evaporation and heat absorption part is formed. The wall body of the rear smoke well 3 is a membrane type heating surface of the superheater, and the heating surface 7 of the serpentine pipe in the cavity of the rear smoke well 3 and the overheating screen 6 in the cavity of the hearth 1 form a heat absorption part of the superheater. The cyclone separator 2 is of a heat insulation type and is formed by pouring a steel plate and a wear-resistant and high-temperature-resistant material. The lower part of the hearth 1 close to the air chamber is provided with a coal feeding point 8 and a feed back leg and hearth interface point 9, and a slag falling port 10 is directly led to the slag falling point from the material accumulation part of the air distribution plate bed. A path of circulating material is led out from the cyclone separator 2 to the interface point 9, and is led into the hearth 1 after the circulating material is heated by the external heat exchanger 17 to heat a steam-water medium. Along with the increase of the boiler capacity, the heat absorption proportion of a superheater is gradually increased, the evaporation heat absorption proportion is reduced, and the heat calculation requirements of the boiler cannot be met by simply amplifying the sizes of a hearth and the like; the number of stages of the steam turbine with increased capacity is correspondingly increased, and the original single flue has no space for adding enough reheaters to supplement the temperature of the secondary cylinder; the increase of the capacity also leads to the increase of the fly ash handling capacity of the cyclone separator, and the arrangement of the cyclone separator with larger quantity can not be arranged on the single-side wall of the hearth, so the traditional circulating fluidized bed boiler structure has certain limitation.

Disclosure of Invention

The to-be-solved technical problem of the utility model is: the traditional circulating fluidized bed boiler structure cannot effectively cope with the problem that the increment of superheater heat absorption is larger than that of evaporation heat absorption along with the increase of boiler capacity, cannot solve the problem that the heating surface of a reheater is not enough in arrangement position, and cannot meet the requirement that more cyclone separators are added into a system.

In order to solve the technical problem, the utility model provides a large capacity circulating fluidized bed boiler, including waterwall furnace, cyclone and back cigarette well, waterwall furnace, cyclone and back cigarette well form the flue gas circulation cavity after being connected with the back cigarette well and absorb heat (including evaporation heat absorption, overheat heat absorption, reheat heat absorption) required heat in order to provide the steam-water system in the heating surface heat absorption, its characterized in that, the heating surface is by arranging the screen structure in waterwall furnace, waterwall furnace's waterwall, cyclone, back cigarette well, the tubular heating surface in the back cigarette well and the water-cooled wall furnace in the wind chamber bottom cold slag heating surface constitute.

Preferably, the screen structure comprises a water cooling screen, an overheating screen and a reheating screen which are arranged in the water cooling wall furnace.

Preferably, the water screen and the water wall of the water wall furnace are arranged in series in the steam-water system, so that the furnace water wall medium is led out from the upper water wall header, heated by the water screen and led into the starting separator.

Preferably, there are 2N of the cyclones, N being a positive integer, and the N cyclones are respectively disposed in front of and behind the furnace.

Preferably, the rear smoke well comprises two double-flue structures, N cyclone separators in the 2N cyclone separators are merged and then enter one double-flue structure, and the rest N cyclone separators in the 2N cyclone separators are merged and then enter the other double-flue structure.

Preferably, the outlet of each double-flue structure is respectively connected with the inlet of an air preheater, and the outlet of the air preheater is connected to the bottom air chamber of the water-cooled wall hearth.

Preferably, the bottom of the water-cooled wall hearth adopts a two-stage slag cooling system, which comprises a first-stage slag cooling system and a slag cooler, wherein a cavity where an economizer hot surface pipe below an air chamber at the bottom of the water-cooled wall hearth is located is used as the first-stage slag cooling system, burned ash on an air distribution plate in the water-cooled wall hearth falls into the first-stage slag cooling system through a slag discharge port at the bottom of the hearth, and is discharged into the slag cooler from the bottom after heat exchange is carried out with a medium in the economizer hot surface pipe of the first-stage slag cooling system.

Preferably, the material return leg of each cyclone separator is divided into two circulating fly ash channels at a certain height, and the two circulating fly ash channels are respectively communicated with two material return ports on the water-cooled wall furnace hearth, so that a double-N-type material return device structure is formed.

Preferably, the coal feeding port is arranged in the circulating fly ash channel, and the coal is fed into the water-cooled wall furnace chamber through the circulating fly ash channel through the coal feeding port.

The serial design of the reclaimed water cooling wall and the water cooling screen in the steam-water system of the utility model increases the retention time of the working medium in the heating surface absorbing heat by evaporation, ensures the saturation of the saturated steam entering the starting separator and can effectively reduce the starting time; the screen structure arranged in the hearth increases the heating area of the superheater and the reheater, the requirement of capacity increase on heat absorption capacity increase of the superheater and the reheater can be met, the number of the cyclone separators is increased, so that the pressure difference in the middle of the hearth is high, and the material can still be uniformly fluidized under the large section of the hearth; the two-stage slag cooling system is characterized in that a heating surface is additionally arranged at the lower part of a slag falling part of the air distribution plate, and the waste heat of ash slag is utilized to improve the boiler efficiency; the cyclone separators are arranged in the front and back, so that the cyclone separators and the hearth interfaces are uniformly distributed on the front side and the back side of the hearth, the bed temperature and the bed pressure are uniform, the pollutant discharge is low, the available range of the size of the cyclone separators is enlarged, the effects of high separation efficiency and low carbon content of fly ash can be achieved, the requirements on the width sizes of the hearth and a rear smoke well are reduced, and the design is more convenient; the coal feeding of the feed back leg can solve the problems of abrasion of a coal feeding pipe and blockage caused by material back-flowing in the furnace, reduces the number of external interfaces of the hearth, the number of pipes jumping in a dense-phase region and unnecessary on-way resistance, and is easier to adjust the total amount of fuel in the hearth in actual operation and convenient to control; the double N-shaped material returning device divides smoke and air entering the hearth of the cyclone separator to participate in circulation into two branches, so that the power consumption of the high-pressure fluidized fan can be reduced, and smooth material returning without pulsation is ensured; the angle of the inlet flue of the rear smoke well is more flexibly taken by adopting the double-double flue, the tubular heating surfaces such as a superheater, a reheater and an economizer can be arranged in the range of each flue, the heating surfaces are more flexibly arranged, and the soot blower arrangement, the flue gas baffle adjustment and the like are more flexibly arranged.

The utility model discloses can satisfy large capacity circulating fluidized bed boiler capacity requirement, the design is nimble, and the regulation performance is good, can adapt to the safe and stable operation of different fuel and assurance boiler.

Drawings

FIG. 1 is a schematic view of a conventional circulating fluidized bed boiler;

FIG. 2 is a schematic structural view of a large-capacity circulating fluidized bed boiler provided by the present invention;

FIG. 3 is a top view of FIG. 2;

fig. 4 is a top view of the lower portion of fig. 2.

Detailed Description

The present invention will be further described with reference to the following specific examples. It should be understood that these examples are for illustrative purposes only and are not intended to limit the scope of the present invention. Furthermore, it should be understood that various changes and modifications of the present invention may be made by those skilled in the art after reading the teachings of the present invention, and these equivalents also fall within the scope of the appended claims.

As shown in fig. 2, the large-capacity circulating fluidized bed boiler disclosed in this embodiment includes a waterwall furnace 1, a cyclone 2, and a rear flue 3. The heated surfaces in the steam-water system can be arranged on the walls of the three components, in the inner cavity, or in the cavity where the economizer hot surface pipe 16 is located under the plenum 15. In the large-scale development process of the circulating fluidized bed boiler, an arrangement mode with an external heat exchanger is often adopted, a high-temperature-level heating surface is arranged in the external heat exchanger, the size of the external heat exchanger can be increased along with the improvement of parameters and capacity, the heat transfer uniformity of the heating surface is difficult to control, the heating surface in the external heat exchanger usually has large wall temperature deviation, and particularly the heating surface of a high-temperature-level reheater in the external heat exchanger is particularly obvious, so that great hidden danger is caused to the reliability of the boiler, and the power consumption of the circulating fluidized bed boiler using the external heat exchanger is high; and a large amount of materials exist in the hearth of the circulating fluidized bed boiler, and although the heat transfer temperature and pressure are low, the heat transfer coefficient and the heat load of the high-temperature heating surface are high. In the low load, the combustion temperature of the hearth is relatively reduced less, the steam temperature capability is better ensured, and on the other hand, because the combustion of the hearth of the circulating fluidized bed boiler is uniform, the steam temperature deviation and the wall temperature deviation of the high-temperature level heating surface can also be well controlled, therefore, a large number of heating surfaces can be arranged in the hearth in a screen structure, and the structure that the external heat exchanger is provided with the high-temperature heating surface is replaced. From the perspective of energy saving, the large-capacity circulating fluidized bed boiler disclosed in the embodiment adopts a single furnace chamber structure without an external heat exchanger, and the high-temperature stage heating surface is arranged in the furnace chamber through the screen structure, so that the external heat exchanger is omitted. The arrangement of the boiler is compact, and compared with the same type scheme, the utility model saves more than 30% of the occupied area, the civil engineering work and the like; the castable of each furnace is saved by about 30 percent, and the purchasing and construction cost of the castable is greatly saved.

The high-temperature flue gas outlet of the water-cooled wall hearth 1 is communicated with the inlet of the cyclone separator 2, the large particle unburned material outlet of the cyclone separator 2 is communicated with the feed back port of the water-cooled wall hearth 1, the small particle burned material outlet of the cyclone separator 2 is communicated with the rear smoke well 3, passes through each heating surface of the rear smoke well, is heated by primary air in the air preheater 14 and is discharged, a basic flue gas flow is formed, and parts such as denitration and the like can be added in the flow as required.

In this embodiment, the water screen 5 and the water wall of the water wall furnace 1 are arranged in series in the steam-water system. Boiler feed water is connected to the wall of the hearth 1 through an economizer heating surface 16 below the air chamber 15, a primary economizer 4 'and a secondary economizer 4' in the rear flue, is led out through a header 18 on the water-cooled wall of the hearth, is heated by a water-cooled screen 5 in the hearth 1 and is led into a starting separator, and the starting separator is an evaporation heat absorption part in a steam-water system. In this embodiment, the low-temperature superheater 7 and the low-temperature reheater 12 are both disposed in the cavity of the rear flue gas shaft 3, and saturated steam led out from the start separator is heated by the low-temperature superheater 7 and the medium (high) temperature superheater 6 and led to the steam turbine, which is a superheating and heat absorbing part in the steam-water system. In this embodiment, the reheated steam led out from the medium (low) pressure cylinder of the steam turbine is heated by the low-temperature reheater 12 and the medium (high) temperature superheater 11 and then led to the steam turbine, which is a reheating heat absorption part in the steam-water system. It should be noted that the cyclone separator 2 and the wall of the connecting channel between it and the furnace 1 or the rear smoke well 3 can be selected from heat insulation, water cooling and steam cooling according to the requirement, and then added into the corresponding steam-water system. Compared with the CFB boiler of internal, international capacity of the same type, the utility model discloses do not adopt external heat exchanger, make stove type combustion system arrange succinctly, operation easy operation reduces the quantity of external bed high pressure fluidization wind simultaneously, practices thrift the station service power, has improved the efficiency of unit.

In this embodiment, the rear smoke well 3 adopts two double-flue structures, namely a left double-flue structure 3' and a right double-flue structure 3 ". The above-described left double flue structure 3' or right double flue structure 3 ″ is formed by providing a partition wall in the middle of the flue structure. For the left double-flue structure 3 'or the right double-flue structure 3 ", each flue structure is divided by a partition wall part, so that the part of the left double-flue structure 3' or the right double-flue structure 3" is a double-flue structure while the rest is still a single-flue structure. The heating surface (including the primary economizer 4 ', the secondary economizer 4', the superheater 7, the reheater 12 and the like) in the rear flue can be arranged in a double-flue structure in the left double-flue structure 3 'or the right double-flue structure 3' or a single-flue structure as required.

Referring to fig. 3, in the present embodiment, there are 8 cyclones 2, wherein 4 cyclones 2 are disposed at the front wall of the waterwall furnace 1, and the other 4 cyclones 2 are disposed at the rear wall of the waterwall furnace 1. Two cyclone separators 2 which are oppositely arranged on the front wall and the rear wall of a water-cooled wall hearth 1 form a group, and two adjacent groups of cyclone separators are combined pairwise and then respectively enter a left double-flue structure 3 'and a right double-flue structure 3'.

The bottom of the water-cooled wall hearth 1 adopts a two-stage slag cooling system which comprises a first-stage slag cooling system and a slag cooler. The burnt-off ash in the water-cooled wall hearth 1 falls into a first-stage slag cooling system through a slag discharge port 10, namely a cavity where an economizer hot surface pipe 16 below an air chamber 15 is located, exchanges heat with a medium in the economizer hot surface pipe 16, and is discharged into a slag cooler from the bottom.

Referring to fig. 4, the solid material outlet of each cyclone 2 is communicated with the feed back port of the waterwall furnace 1 through a feed back leg. The utility model discloses a feed back leg has adopted novel two N type feed back structures, particularly, the feed back leg of 2 bottoms of every cyclone falls into two circulation flying dust passageways to controlling in the take the altitude department, has reserved coal feed mouth 8 on two circulation flying dust passageways respectively, solves coal supply pipe wearing and tearing and block up the problem.

The outlets of the left double-flue structure 3 'and the right double-flue structure 3' are respectively connected with the inlet of an air preheater 14, and the outlet of the air preheater 14 is connected to the bottom air chamber 15 of the water-cooled wall hearth 1.

Claims (9)

1. A large-capacity circulating fluidized bed boiler comprises a water-cooled wall hearth, a cyclone separator and a rear smoke well, wherein the water-cooled wall hearth and the cyclone separator are connected with the rear smoke well to form a smoke circulation cavity to provide heat required by heat absorption of a heating surface in a steam-water system.

2. A large capacity circulating fluidized bed boiler in accordance with claim 1, wherein said screen structure comprises a water screen, an overheating screen and a reheating screen arranged in said waterwall furnace.

3. A large capacity circulating fluidized bed boiler in accordance with claim 2, wherein the water screen and the water walls of the waterwall furnace are arranged in series in the steam-water system such that the furnace waterwall media is introduced from the upper waterwall header, heated by the water screen, and introduced to the start-up separator.

4. A large capacity circulating fluidized bed boiler in accordance with claim 1, wherein there are 2N said cyclone separators, N being a positive integer, and N said cyclone separators are disposed at the front and rear of the furnace, respectively.

5. A large capacity circulating fluidized bed boiler in accordance with claim 4, wherein said rear chimney comprises two double flue structures, N of said 2N cyclones being merged into one double flue structure, and the remaining N of said 2N cyclones being merged into the other double flue structure.

6. A large capacity circulating fluidized bed boiler in accordance with claim 5, wherein the outlet of each of said double flue structures is connected to the inlet of an air preheater, the outlet of which is connected to the bottom plenum of said waterwall furnace.

7. A large capacity circulating fluidized bed boiler as claimed in claim 1, wherein the bottom of the waterwall furnace is provided with a two-stage slag cooling system, which comprises a first stage slag cooling system and a slag cooler, the cavity of the economizer hot side tube below the plenum at the bottom of the waterwall furnace is used as the first stage slag cooling system, the burnt ash on the air distribution plate in the waterwall furnace falls into the first stage slag cooling system through the slag discharge port at the bottom of the furnace, and the burnt ash is discharged into the slag cooler from the bottom after exchanging heat with the medium in the economizer hot side tube of the first stage slag cooling system.

8. A large capacity circulating fluidized bed boiler as claimed in claim 1, wherein the return leg of each cyclone is divided into two circulating fly ash passages at a certain height, and the two circulating fly ash passages are respectively communicated with the two return ports of the waterwall furnace chamber, thereby forming a double N-type feed back structure.

9. A large capacity circulating fluidized bed boiler according to claim 8, wherein a coal supply port is provided in said circulating fly ash passage, and coal is supplied into said waterwall furnace through said circulating fly ash passage through said coal supply port.

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