CN114688546B - Hot ash returning flow control device and method capable of achieving lateral air distribution and achieving double adjustment of bed temperature and steam temperature - Google Patents

Abstract

The invention discloses a hot ash returning flow control device and a method for realizing lateral air distribution of double adjustment of bed temperature and steam temperature. The partition board in the main bed divides the main bed into a first chamber and a second chamber of the main bed and is respectively provided with a heating surface, the top and the bottom of the partition board are provided with a passage between the two chambers, so that hot ash can flow conveniently, and the hot ash flowing out of each return pipe after heat exchange is converged into a return main pipeline and returns to a hearth. The invention can effectively regulate and control the heat absorption capacity and the ash temperature of the tube bundle, further regulate the bed temperature and realize double accurate regulation and control of the bed temperature and the smoke temperature; multiple heat exchangers can be arranged, and SO caused by the fact that the heating surface is arranged in the tail flue is avoided ₂ High-temperature flue gas and accumulated ash such as HCl and the like are corroded, can stably operate, reduces operation and maintenance cost, and is suitable for the circulating fluidized bed garbage incinerator.

Description

Hot ash returning flow control device and method capable of achieving lateral air distribution and achieving double adjustment of bed temperature and steam temperature

Technical Field

The invention belongs to the field of design of external heat exchangers of circulating fluidized bed waste incineration boilers, and particularly relates to a hot ash return flow control device and method capable of achieving lateral air distribution and achieving double bed temperature and steam temperature adjustment.

Background

The circulating fluidized bed boiler has good adaptability to garbage components, and is gradually applied to harmless treatment of household garbage in recent years. With the large-scale of the boiler capacity and specification, the furnace and the tail flue cannot provide enough heating surfaces, so that the arrangement of part of the heating surfaces in the external heat exchanger becomes the current development trend. The external heat exchanger can effectively adjust the flow of ash returning to the hearth, so that the heat absorption capacity of the furnace temperature and the internal heat exchanger can be flexibly adjusted; the heating surface is transferred into the external heat exchanger from the tail flue, SO that SO can be effectively prevented ₂ And high temperature flue gas and ash deposition corrosion of HCl.

However, in actual operation, the phenomenon of unsmooth material return of the external heat exchanger often occurs, which is because the phenomenon of ash blockage and even reverse channeling often occurs in a downcomer connecting the external heat exchanger and the cyclone separator. Therefore, the structural design of the existing external heat exchanger needs to be optimized, so that the heat exchanger can ensure effective heat exchange of high-temperature hot ash in the external heat exchanger, can adjust the flow of returned materials according to the temperature requirement of a hearth, and avoids the problem of ash accumulation or reverse channeling caused by too low or too high fluidizing air speed in the adjusting process.

In addition, present ash device that returns, the structure is general more single, can't realize the dual accurate regulation and control of heat transfer volume and circulation flow, and the bed material that often can appear returning to in the furnace from external heat exchanger is still high in temperature, and is less with the difference in temperature of furnace bed temperature, is unfavorable for that the furnace temperature is in reasonable within range, and the bed temperature of high partially makes the lime-ash that will discharge furnace easily present the vitrification state, blocks up the slag pipe, consequently how to realize effectively accurate heat transfer and adjust the bed temperature, just seems to be particularly important.

In the existing patent documents for designing external heat exchangers of garbage incinerators, for example, the document with the application number of CN201510592260.7 discloses a material returning valve with an adjustable tongue plate, the actual operation condition of a loosening chamber at one side of a descending pipe is not considered, bed materials are easy to accumulate and reverse to flee, the phenomenon of bridging in the descending pipe is caused, and the stable operation of the material returning valve is influenced.

Disclosure of Invention

The invention mainly aims to overcome the defects of the prior art, and provides a hot ash returning flow control device and a method for realizing lateral air distribution of bed temperature and steam temperature double regulation, so as to solve the problems that the existing external heat exchanger of a garbage incinerator is easy to have unsmooth material return such as ash accumulation and reverse channeling in operation, cannot realize effective heat exchange, influences ash circulation and simultaneously realizes bed temperature regulation and overall normal operation of a boiler.

The invention firstly provides a hot ash returning flow control device capable of realizing side air distribution and realizing double adjustment of bed temperature and steam temperature, which comprises a downcomer and is characterized by also comprising four small hot ash returning devices and a main side air pipeline, wherein heat exchange surfaces of different types and quantities are arranged in each hot ash returning device;

four top lateral air distribution pipelines are arranged on the outer wall of the downcomer, and the joints of the four top lateral air distribution pipelines and the downcomer are arranged in a cross shape; the four small-sized hot ash returning devices (with the same or similar structures) are also arranged in a cross shape;

each small-sized hot ash returning device comprises a main bed, an auxiliary bed, a returning pipe and an air distribution plate; wherein, the auxiliary bed is connected with a down pipe, the bottom of the auxiliary bed is provided with an inclined section, and the inclined section is provided with a bottom lateral air distribution pipeline; a partition plate is arranged in the main bed, the partition plate divides the main bed into a main bed second chamber and a main bed first chamber, the top and the bottom of the main bed second chamber are communicated, and a first heating surface and a second heating surface are respectively arranged in the main bed first chamber and the main bed second chamber; the bottoms of the first main bed chamber and the second main bed chamber are provided with slag discharge pipes; the air distribution plate is positioned at the bottom of the main bed, and an air cap is arranged on the air distribution plate; the bottom of the auxiliary bed is communicated with a second main bed chamber, and the first main bed chamber is connected with a material return pipe;

the lateral wind main pipeline is respectively connected with the lateral wind distribution pipeline at the bottom of each small hot ash returning device;

after the return material manifolds of the four small hot ash returning devices are combined into a main pipeline, the return material manifolds return to the hearth in a unified way.

As a preferred scheme of the invention, the first main bed chamber and the second main bed chamber are respectively supplied with air independently through the air distribution plate by respective corresponding air chambers, so that the accurate regulation and control of the flow rate are realized.

As a preferred scheme of the present invention, the first heating surface and the second heating surface of different types and areas can be respectively arranged in the first main bed chamber and the second main bed chamber according to actual needs, so as to realize the simultaneous heat exchange of the heating surfaces with different heat absorption needs in the main bed.

In a preferred embodiment of the present invention, the partition is disposed at a certain intermediate height, and is not connected to the main bed at the upper and lower sides thereof, thereby forming a hot ash flow path connecting the first main bed chamber and the second main bed chamber.

As a preferable scheme of the invention, a metal screen and an electric valve are arranged in a bottom side air distribution pipeline of the inclined section at the bottom of the auxiliary bed, wherein the metal screen is arranged at one side close to the auxiliary bed to prevent hot ash from flowing into the pipeline to influence the normal operation of the electric valve.

In a preferred embodiment of the present invention, the bottom side air distribution pipes of the inclined bottom sections of the sub-beds of each small-sized hot ash return flow rate control device are all from the bottom side air main pipe, and the opening of each bottom side air distribution pipe is adjusted by an electric valve arranged therein, so that the side air blowing rate flowing into each sub-bed is controlled.

As a preferable scheme of the invention, the number of the heating surfaces arranged in the main bed of the four small-sized hot ash returning flow control devices is not completely the same, the heating surfaces in one part of the devices are more, the heating surfaces in the other part of the devices are less, and the hot ash can be blown into each small-sized hot ash returning flow control device under the action of the lateral wind of the descending pipe according to different proportions according to the requirements of the actual bed temperature and air temperature during operation.

As a preferable scheme of the invention, the auxiliary bed is a middle area connecting a downcomer and a main bed in each small-sized hot ash returning device, and is divided into two parts along the height, wherein the upper part is a vertical section with a triangular prism structure, and the lower part is an inclined section; the bottom of the inclined section of the auxiliary bed is provided with a bottom side air distribution pipeline in the horizontal direction, and the bottom side air distribution pipeline is used for blowing hot ash into the main bed, so that the phenomenon that a material layer is excessively high in accumulation or the hot ash is reversed is avoided; the auxiliary bed is surrounded by a front wall and a rear wall, wherein the main bed and the auxiliary bed are separated by the front wall, a channel for communicating the main bed and the auxiliary bed is reserved at the bottom of the front wall, the rear wall of the vertical section comprises two vertical surfaces, and the two vertical surfaces and the front wall surface form a triangular structure; the rear wall of the inclined section has an inclined surface inclined toward the front wall for guiding the hot ashes to the main bed.

As a preferable scheme of the invention, the heat exchange tube bundles of the first heated surface and the second heated surface in the main bed are arranged along the horizontal direction.

The invention also discloses a working method of the adjustable double-bed anti-corrosion external high-temperature superheater ash return device, wherein a down pipe is communicated with an upstream cyclone separator, and a material return port is communicated with a hearth through a material return pipe;

when the cyclone separator works, high-temperature hot ash separated from the cyclone separator falls into the downcomer, the high-temperature hot ash respectively flows into the auxiliary beds of the four small-sized hot ash return flow control devices in different proportions under the blowing action of the top lateral air distribution pipeline arranged on the outer wall of the downcomer, the hot ash passes through the vertical section of the auxiliary beds and then falls into the bottom inclined section, a certain height can be accumulated in the auxiliary beds according to the circulating ash amount in actual operation, the hot ash in the inclined section of the auxiliary beds can fall along the inclined plane under the action of gravity, part of the hot ash can flow into the main beds to participate in fluidization and heat exchange processes, and then the hot ash flows into the main beds under the blowing action of the bottom lateral air distribution pipeline of the bottom inclined section of the auxiliary beds, and due to lateral air distribution, the hot ash can be blown out in the horizontal direction rather than the vertical direction, so that a large amount of reverse channeling and even bridging of the hot ash can not occur, but can directly flow into the main beds under the action of lateral fluidized air; fluidized air in the main bed is uniformly sprayed out after passing through the air caps on the air distribution plate, and drives hot ash to perform sufficient heat exchange with the first heating surface and the second heating surface in the first chamber of the main bed and the second chamber of the main bed respectively, the hot ash in the second chamber of the main bed can flow into the first chamber of the main bed through the top passage to continuously participate in the heat exchange and also can flow into the first chamber of the main bed through the bottom passage, the hot ash returns to a hearth through the material return pipe after performing sufficient heat exchange with the heating surface, and the slag discharge pipe is opened when the operation is stopped and is used for discharging slag.

The main air supply pipeline of the invention is divided into four lateral air supplies at the inclined section near the auxiliary bed, and the four lateral air supplies are respectively introduced into four small hot ash returning devices.

In a preferred embodiment of the invention, the heat exchange tube bundle is arranged in the main bed along the horizontal direction, and the structural design can avoid the problems that the tube bundle interferes the flow of the side wind flowing from the auxiliary bed and affects the loosening effect of the side wind, and the tube bundle is arranged along the height direction and is easy to cause uneven heat exchange, large temperature difference and thermal stress damage and the like.

In a preferred embodiment of the present invention, each small hot ash returning device is divided into a first main bed chamber and a second main bed chamber by a partition board arranged at an intermediate height, and heating surfaces are respectively arranged in the first main bed chamber and the second main bed chamber, so that compared with the case that no partition board is arranged, the arrangement is favorable for respectively performing precise control on the requirements of each heating surface (such as a high temperature reheater, a medium temperature superheater, etc.), and thus, the double regulation of the hearth bed temperature and the steam temperature is realized.

In a preferred embodiment of the invention, a metal screen and an electric valve are arranged in the ventilation pipeline arranged on the side wall at the bottom of the feeding section, the metal screen is used for preventing ash materials from rushing into the ventilation hole to cause blockage, adhesion and the like when side wind stops running, so that normal blast is influenced, and the electric valve is used for flexibly adjusting the opening degree, so that the blast air quantity flowing into the auxiliary bed is adjusted and controlled.

The quantity (corresponding heated area) of the heat exchange tube bundles arranged in each small-sized hot ash returning device is different, the hot ash falls into the auxiliary bed through the descending tube in the process, the top lateral air distribution pipeline arranged on the outer wall of the descending tube can automatically adjust the air blowing quantity to blow the hot ash according to the working condition requirement, and the flow proportion of the hot ash falling into each small-sized hot ash returning device is adjusted, so that the heat absorption quantity is adjusted.

Compared with the prior art, the invention has the following advantages:

(1) The invention can be applied to the arrangement of the heating surfaces of a high-temperature superheater, a low-temperature superheater, a high-temperature reheater and the like of the circulating fluidized bed garbage incinerator, the lateral air distribution at the bottoms of the downcomer and the auxiliary bed can realize the accurate adjustment of the return flow of hot ash and the heat absorption capacity of the heat exchanger, the adjustment of the hearth bed temperature and the steam temperature is facilitated, the serious corrosion of flue gas containing a large amount of sulfur and chlorine caused by the arrangement of the heating surfaces in a tail flue is avoided, and the damage and the maintenance cost caused by the corrosion to the long-time stable operation are reduced.

(2) The invention utilizes the partition board arranged at the middle height of the main bed to divide the main bed into a first main bed chamber and a second main bed chamber in the horizontal direction, and a top channel and a bottom channel are arranged between the two chambers in the height direction, so that the structural characteristics of the hot ash returning device can be quickly and effectively adjusted, thereby arranging heating surfaces with different heat exchange requirements in a single returning device, and adjusting air volume in a targeted manner to carry out fluidized heat exchange, thereby being beneficial to flexibly adjusting the heat exchange quantity and the returning quantity.

(3) In combination with the phenomena of ash material channeling, unsmooth blanking and returning and the like in actual operation, considering that the motion characteristics of the hot ash in the main bed and the auxiliary bed are not completely the same, the hot ash in the main bed can be fluidized more sufficiently, and therefore a lateral wind and a bottom inclined section are arranged on one side of the auxiliary bed to strengthen the flow of the hot ash in the auxiliary bed.

(4) The heat exchange tube bundle is arranged along the horizontal direction, but not the vertical direction, so that the hot ash flowing in from the channel at the top of the partition plate can be prevented from being blocked by the heating surface and cannot smoothly and effectively enter the first chamber of the main bed; fluidization in the main bed is difficult to ensure that the heat exchange is even along the direction of height, and the horizontal direction is because same height, and the heat transfer effect is unanimous basically, therefore the tube bank is arranged along the horizontal direction and also can be avoided the tube bank to be heated unevenly, and the temperature difference is too big and suffer thermal stress destruction, influence the safety of hot ash loopback device, steady operation.

Drawings

FIG. 1 is a schematic cross-sectional view of a lateral air distribution hot ash return flow control device and method for achieving dual bed temperature and steam temperature control according to the present invention;

FIG. 2 is a sectional view of the structure A-A of the lateral air distribution hot ash return flow control device and method for realizing dual adjustment of bed temperature and steam temperature according to the present invention;

FIG. 3 is a schematic structural diagram of a single small hot ash recovery device;

FIG. 4 is a B-B structural cross-sectional view of a single small-sized hot ash returning device.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

It should be noted that all the directional indicators (such as up, down, left, right, front, and back … …) in the present invention are only used to explain the relative position relationship between the components, the motion situation, etc. in a specific posture (as shown in the figure), and if the specific posture is changed, the directional indicator is changed accordingly.

In the present invention, unless otherwise expressly stated or limited, the terms "connected," "secured," "disposed" and the like are to be construed broadly, e.g., "secured" may be a fixed connection, a removable connection, or an integral part; the connection can be mechanical connection, electrical connection, physical connection or wireless communication connection; they may be directly connected or indirectly connected through intervening media, or they may be connected internally or in any other suitable relationship, unless expressly stated otherwise. The specific meanings of the above terms in the present invention can be understood by those skilled in the art according to specific situations.

The present invention will be described in further detail below with reference to the accompanying drawings.

Fig. 1 is a schematic cross-sectional view of a hot ash returning flow control device capable of achieving double bed temperature and steam temperature adjustment and lateral air distribution according to the present invention, which includes a downcomer 2, four small hot ash returning devices with identical structures, and a main lateral air pipeline 10, wherein different types and numbers of heat exchange surfaces are arranged in each hot ash returning device;

four top lateral air distribution pipelines 1 are arranged on the outer wall of the down pipe, and the joints of the four top lateral air distribution pipelines and the down pipe are arranged in a cross shape; the four small-sized hot ash returning devices with the same structure are also arranged in a cross shape;

each small-sized hot ash returning device comprises a main bed, an auxiliary bed, a returning pipe 7 and an air distribution plate 17; wherein, the auxiliary bed is connected with a down pipe, the bottom of the auxiliary bed is provided with an inclined section, and the inclined section is provided with a bottom lateral air distribution pipeline 9; a partition plate 5 is arranged in the main bed, the partition plate divides the main bed into a second main bed chamber 4 and a first main bed chamber 8, the top and the bottom of the second main bed chamber 4 are communicated, and a first heating surface 6 and a second heating surface 14 are respectively arranged in the first main bed chamber 8 and the second main bed chamber 4; the bottoms of the primary bed first chamber 8 and the primary bed second chamber 4 are both provided with a slag discharge pipe 12; the air distribution plate 17 is positioned at the bottom of the main bed, and an air cap 11 is arranged on the air distribution plate 17; the bottom of the auxiliary bed is communicated with a second main bed chamber 4, and a first main bed chamber 8 is connected with a return pipe 7;

the lateral wind main pipeline 10 is respectively connected with the bottom lateral wind distribution pipeline 9 of each small-sized hot ash returning device;

the return pipes 7 of the four small hot ash returning devices with the same structure are converged into a main pipeline and then uniformly returned to the hearth.

In the whole boiler circulation loop, a downcomer 2 is communicated with an outlet at the bottom of a cyclone separator, a material returning pipe 7 is communicated with a hearth, and the whole device, the hearth, the separator and the like form a hot ash circulation loop together.

The air distribution plate 17 is provided with an air cap 11, the first main bed chamber 8 and the second main bed chamber 4 are provided with respective air supply pipelines, air is independently supplied during operation, flow regulation of respective chambers is realized, the number of tube bundles of the first heating surface 6 and the second heating surface 14 arranged in the air distribution plate can be specifically adjusted according to requirements, and therefore heat exchange of heat exchangers required by different heat exchange temperatures in the main bed is realized.

The first heating surfaces 6 and the second heating surfaces 14 with different quantities are arranged in the four small-sized hot ash returning flow control devices, and the returning pipes 7 of the four small-sized hot ash returning flow control devices are firstly converged at the bottom of the device to form a returning main pipeline and then are connected with the hearth.

During operation, the hot ash that comes off from cyclone separates behind the export of separator bottom, falls into downtake 2, according to the needs of furnace bed temperature and steam temperature, adjusts the blowing volume of four top side direction air distribution pipelines 1 that set up on downtake outer wall 3 to adjust the hot ash and fall into the concrete proportion in four small-size hot ash loopback flow control device, for example furnace bed temperature is higher, then correspondingly through the side direction wind increase hot ash fall arrange the loopback device that the heating surface is more, just can return furnace with microthermal form after abundant heat transfer, effectively reduce the bed temperature. In each small-sized hot ash returning flow control device, hot ash falls into a secondary bed 15 through a downcomer 2, is blown to flow into a second main bed chamber 4 under the action of a bottom side air distribution pipeline 9 of an inclined section at the bottom of the secondary bed 15, fully exchanges heat with a second heated surface 14 under the action of fluidized air sprayed from an air cap 11 on an air distribution plate 17, flows into a first main bed chamber 8 along a top passage and a bottom passage, exchanges heat with a first heated surface 6, finally flows into a material returning pipe 7 through a material returning port, and finally, the four material returning pipes 7 are converged at one position, returns the hot ash into a hearth in a form of a main pipe, adjusts the bed temperature and participates in next material circulation.

When the air distribution device works, the electric valve 16 in each bottom side air distribution pipeline 9 adjusts the opening according to the blanking condition of the auxiliary beds 15, so that the blowing air quantity entering each auxiliary bed 15 is controlled.

After the device stops working, the slag discharge pipe 12 is opened to discharge slag from the bottom.

According to the hot ash returning flow control device capable of realizing the lateral air distribution of the double adjustment of the bed temperature and the steam temperature, the top lateral air distribution pipeline 1 at the position of the downcomer 2 is added, and the flow of hot ash falling into each small hot ash returning flow control device with different heating surfaces can be adjusted by utilizing the form of blowing lateral air, so that the heat exchange quantity is effectively adjusted; the inclined section and the bottom side air distribution pipeline 9 of the auxiliary bed 15 are additionally provided, and the electric valve 16 and the metal screen 13 are arranged in the auxiliary bed, the metal screen 13 can effectively avoid the blockage of hot ash flowing into the pipeline, the electric valve 16 can effectively control the opening degree, adjust the blowing air quantity flowing into each auxiliary bed 15, and further adjust the hot ash quantity flowing into the second chamber 4 of the main bed, and the hot ash can smoothly enter the second chamber 4 of the main bed under the action of gravity and side wind by combining the inclined section of the auxiliary bed 15.

The adjustable double-bed corrosion-resistant external high-temperature superheater ash returning device of the invention is described in detail above, and specifically, the working principle, the flow and the specific features of the invention are explained, and the above description is only used to help understanding the core idea of the invention, and meanwhile, for a person skilled in the art, by adopting the idea of the invention, corresponding modifications may be made in the specific implementation and the application range of the invention. In view of the above, the present disclosure should not be construed as limiting the invention.

Claims (10)

1. A hot ash returning flow control device capable of realizing side wind distribution and capable of achieving double adjustment of bed temperature and steam temperature comprises a downcomer (2) and is characterized by further comprising four small hot ash returning devices and a side wind main pipeline (10), wherein heat exchange surfaces of different types and numbers are arranged in each hot ash returning device;

four top lateral air distribution pipelines (1) are arranged on the outer wall of the downcomer, and the joints of the four top lateral air distribution pipelines and the downcomer are arranged in a cross shape; the four small-sized hot ash returning devices are also arranged in a cross shape;

each small-sized hot ash returning device comprises a main bed, an auxiliary bed, a returning pipe (7) and an air distribution plate (17); wherein, the auxiliary bed is connected with the downcomer, the bottom of the auxiliary bed is provided with an inclined section, and the inclined section is provided with a bottom lateral air distribution pipeline (9); a partition plate (5) is arranged in the main bed, the partition plate divides the main bed into a main bed second chamber (4) and a main bed first chamber (8), the top and the bottom of the main bed second chamber are communicated, and a first heating surface (6) and a second heating surface (14) are respectively arranged in the main bed first chamber (8) and the main bed second chamber (4); the bottoms of the primary bed first chamber (8) and the primary bed second chamber (4) are provided with slag discharge pipes (12); the air distribution plate (17) is positioned at the bottom of the main bed, and an air cap (11) is arranged on the air distribution plate (17); the bottom of the auxiliary bed is communicated with a second main bed chamber (4), and a first main bed chamber (8) is connected with a material return pipe (7);

the lateral wind main pipeline (10) is respectively connected with the lateral wind distribution pipeline (9) at the bottom of each small-sized hot ash returning device;

the return pipes (7) of the four small-sized hot ash returning devices are converged into a main pipeline and then uniformly returned to the hearth.

2. The device for controlling the flow rate of returning hot ash through lateral air distribution capable of achieving double adjustment of bed temperature and steam temperature as claimed in claim 1, wherein the primary bed chamber (8) and the primary bed chamber (4) are independently supplied with air from respective corresponding air chambers through an air distribution plate (17), so as to achieve precise adjustment and control of the flow rate.

3. The hot ash returning flow control device capable of realizing the lateral air distribution with the double bed temperature and steam temperature adjustment is characterized in that the first heating surface (6) and the second heating surface (14) with different types and areas can be respectively arranged in the first bed chamber (8) and the second bed chamber (4) according to actual needs, and are used for realizing the simultaneous heat exchange of the heating surfaces with different heat absorption needs in the main bed.

4. The flow control device for returning hot ash with lateral air distribution capable of realizing double adjustment of bed temperature and steam temperature as claimed in claim 1, characterized in that the partition plate (5) is arranged at a certain middle height, and the upper part and the lower part of the partition plate are not connected with the main bed, so that a hot ash flow passage connecting the first chamber (8) of the main bed and the second chamber (4) of the main bed is formed.

5. The hot ash return flow control device capable of realizing the lateral air distribution of the double-temperature regulation of the bed and the steam is characterized in that a metal screen (13) and an electric valve (16) are arranged in a bottom lateral air distribution pipeline (9) of the inclined section at the bottom of the secondary bed, wherein the metal screen (13) is arranged at one side close to the secondary bed (15) to prevent the hot ash from flowing into a pipeline to influence the normal operation of the electric valve (16).

6. The thermal ash return flow control device for lateral air distribution capable of achieving double adjustment of bed temperature and steam temperature according to claim 5, characterized in that the bottom lateral air distribution pipeline (9) of the sub-bed bottom inclined section of each small thermal ash return flow control device is from the bottom lateral air distribution main pipeline (10), and the opening of each bottom lateral air distribution pipeline (9) is adjusted by an electric valve (16) respectively arranged therein, so as to adjust and control the lateral air blowing amount flowing into each sub-bed (15).

7. The device for controlling the flow rate of returning hot ash with lateral air distribution capable of achieving dual adjustment of bed temperature and steam temperature as claimed in claim 1, wherein the number of the heating surfaces arranged inside the main bed of the four small-sized devices for controlling the flow rate of returning hot ash is not exactly the same, and more heating surfaces are arranged in some devices and less heating surfaces are arranged in other devices, so that the hot ash can be blown into each small-sized device for controlling the flow rate of returning hot ash under the action of the lateral air of the down pipe according to different proportions according to the requirements of the actual bed temperature and air temperature during operation.

8. The device for controlling the flow rate of returning hot ash with lateral air distribution capable of achieving double adjustment of bed temperature and steam temperature as claimed in claim 1, wherein the secondary bed is a middle area of each small-sized hot ash returning device connecting the downcomer and the primary bed, and is divided into two parts along the height, the upper part is a vertical section of a triangular prism structure, and the lower part is an inclined section; the bottom of the inclined section of the auxiliary bed is provided with a bottom side air distribution pipeline (9) in the horizontal direction, and the bottom side air distribution pipeline is used for blowing hot ash into the main bed to avoid overhigh accumulation or reverse flow of the hot ash; the auxiliary bed is surrounded by a front wall and a rear wall, wherein the main bed and the auxiliary bed are separated by the front wall, a channel for communicating the main bed and the auxiliary bed is reserved at the bottom of the front wall, the rear wall of the vertical section comprises two vertical surfaces, and the two vertical surfaces and the front wall surface form a triangular structure; the rear wall of the inclined section has an inclined surface inclined toward the front wall for guiding the hot ashes to the main bed.

9. The device for controlling the flow rate of returning hot ash with laterally distributed wind and capable of achieving double adjustment of bed temperature and steam temperature as claimed in claim 1, wherein the heat exchange tube bundles of the first heating surface and the second heating surface in the main bed are arranged along the horizontal direction.

10. The working method of the hot ash returning flow control device capable of realizing the lateral air distribution with the dual bed temperature and steam temperature regulation of the claim 1 is characterized in that a downcomer (2) is communicated with an upstream cyclone separator, and a return pipe (7) is communicated with a hearth;

when the cyclone dust collector works, high-temperature hot dust separated from the cyclone separator falls into the downcomer (2), and respectively flows into the auxiliary beds (15) of the four small-sized hot dust returning flow control devices in different proportions under the blowing action of the top side air distribution pipeline (1) arranged on the outer wall (3) of the downcomer, the hot dust passes through the vertical section of the auxiliary beds and then falls into the bottom inclined section, a certain height can be accumulated in the auxiliary beds according to the circulating dust amount in actual operation, the hot dust in the inclined section of the auxiliary beds can fall along the inclined plane under the action of gravity, part of the hot dust can flow into the main beds to participate in fluidization and heat exchange processes, and then the hot dust flows into the main beds under the blowing action of the bottom side air distribution pipeline (9) of the bottom inclined section of the auxiliary beds (15), and the hot dust can be blown out in the horizontal direction instead of the vertical direction due to side air distribution, so that a large amount of reverse channeling and even bridging of the hot dust can not occur, but can directly flow into the main beds under the action of side fluidization air; fluidized air in the main bed is uniformly sprayed out after passing through an air cap (11) on an air distribution plate (17), and drives hot ash to perform sufficient heat exchange with a first heating surface (6) and a second heating surface (14) in a first chamber (8) and a second chamber (4) of the main bed respectively, the hot ash in the second chamber (4) of the main bed can flow into the first chamber (8) of the main bed through a top passage to continuously participate in the heat exchange and also can flow into the first chamber (8) of the main bed through a bottom passage, the hot ash and the heating surfaces perform sufficient heat exchange and then return to a hearth through a return pipe (7), and a slag discharge pipe (12) is opened when the operation is stopped for discharging slag.

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