CN113941593B

CN113941593B - Miniaturized high concentration pollutes soil dystopy thermal desorption system

Info

Publication number: CN113941593B
Application number: CN202111157259.3A
Authority: CN
Inventors: 唐晓声; 李海建; 王书倩; 陈昱
Original assignee: Jiangsu Yangtze River Delta Environmental Science And Technology Research Institute Co ltd
Current assignee: Jiangsu Yangtze River Delta Environmental Science And Technology Research Institute Co ltd
Priority date: 2021-09-30
Filing date: 2021-09-30
Publication date: 2023-02-28
Anticipated expiration: 2041-09-30
Also published as: CN113941593A

Abstract

The invention provides a miniaturized high-concentration polluted soil ex-situ thermal desorption system, which comprises a rotary kiln, a secondary combustion chamber, a dust removal filter, a heat exchange cooler and a desulfurizing tower, and is characterized in that: the heat exchange cooler is internally provided with a first heat exchange pipeline and a second heat exchange pipeline, two ends of the second heat exchange pipeline extend out of the heat exchange cooler and are respectively connected with the air inlet pipeline and the air outlet pipeline, the air outlet pipeline is connected with a six-way valve, a first air outlet of the six-way valve is communicated with an auxiliary air inlet of the rotary kiln through a first conveying pipeline, a second air outlet of the six-way valve is communicated with an auxiliary air inlet of the secondary combustion chamber through a second conveying pipeline, and a third air outlet of the six-way valve is connected with a hot air delivery pipeline. The invention collects the heat of the flue gas discharged from the second combustion chamber by using the heat exchange cooler, and conveys the collected heat into the rotary kiln and the second combustion chamber again by using the air, so that the energy loss can be effectively reduced, and the cost is reduced.

Description

Miniaturized high concentration pollutes soil dystopy thermal desorption system

Technical Field

The invention relates to the technical field of soil remediation, in particular to a miniaturized high-concentration contaminated soil ex-situ thermal desorption system.

Background

With the development of industry and agriculture and the acceleration of urbanization process, the adjustment of industrial structure and the acceleration of urbanization process, a large number of polluted enterprises relating to industries such as chemical industry, metallurgy, petroleum, transportation, light industry and the like are moved or closed in sequence. In the process of re-development and utilization of volatile pollutants in soil in a plurality of industrial enterprises removed and left sites, the volatile and semi-volatile pollutants in the soil can enter other environment media through gas-soil circulation and water-soil circulation, and can also directly enter human bodies through food chains or human breath to harm human health. Volatile and semi-volatile pollutants in the soil are listed as toxic pollutants which have high potential danger and need to be controlled preferentially in the environment.

At present, the repair technology for polluted soil has two modes of in-situ repair and ex-situ repair, wherein:

the in-situ remediation of the polluted soil does not need to excavate and transport the soil, so the required engineering amount is relatively small, and the common processes comprise in-situ vapor extraction, in-situ chemical remediation and the like, but the in-situ treatment processes generally have the defects of long treatment time, low treatment efficiency, low removal rate of volatile and semi-volatile pollutants and the like, and the problems of secondary pollution and the like possibly caused by the in-situ chemical remediation process;

the common techniques for ex-situ remediation of contaminated soil include ex-situ thermal desorption treatment, ex-situ chemical remediation, etc., wherein the ex-situ thermal desorption treatment has a good effect, and the ex-situ thermal desorption treatment uses a rotary kiln as thermal desorption equipment and is widely applied. When the rotary kiln is adopted to treat the polluted soil, the polluted soil is turned in the rotary kiln and exchanges heat with the retrograde flue gas, so that the purpose of removing volatile and semi-volatile pollutants from the soil is achieved; however, the flue gas passing through the secondary combustion chamber is usually directly cooled, and heat is not recycled, so that great energy waste is caused, and the cost is greatly increased.

Moreover, the existing ex-situ thermal desorption systems are large-scale, require a large floor space during installation, and are inconvenient to install and maintain, so that the design of a miniaturized ex-situ thermal desorption system for high-concentration contaminated soil is particularly important in order to solve the problems, and the miniaturization is also an important research and development direction of the ex-situ thermal desorption system.

Disclosure of Invention

The invention provides a miniaturized high-concentration polluted soil ex-situ thermal desorption system, which is characterized in that a heat exchange cooler is utilized to collect the heat of flue gas exhausted from a secondary combustion chamber, and the collected heat is conveyed into a rotary kiln and the secondary combustion chamber again through air, so that the energy loss can be effectively reduced, and the cost is reduced; and the temperature of the discharged gas can be reduced, and the adverse effect on the surrounding environment can be reduced.

In order to solve the technical problem, the invention provides a miniaturized high-concentration polluted soil ex-situ thermal desorption system, which comprises a rotary kiln, a secondary combustion chamber, a dust removal filter, a heat exchange cooler and a desulfurizing tower, and is characterized in that: the rotary kiln is a small rotary kiln, the second combustion chamber is a horizontal small second combustion chamber, the dust removal filter consists of an active carbon dust removal filtering system and a bag-type dust remover, an air outlet of the rotary kiln is communicated with the active carbon dust removal filtering system through a first flue gas conveying pipeline, the active carbon dust removal filtering system is communicated with an air inlet of the second combustion chamber through a second flue gas conveying pipeline, an air outlet of the second combustion chamber is communicated with a flue gas accelerating device through a third flue gas conveying pipeline, the flue gas accelerating device is communicated with a flue gas inlet of a heat exchange cooler through a fourth flue gas conveying pipeline, a flue gas outlet of the heat exchange cooler is communicated with an air inlet of the bag-type dust remover through a fifth flue gas conveying pipeline, an air outlet of the bag-type dust remover is communicated with a desulfurizing tower through a sixth flue gas conveying pipeline, and a first air pump is installed on the sixth flue gas conveying pipeline;

the heat exchange cooler is internally provided with a first heat exchange pipeline and a second heat exchange pipeline, the first heat exchange pipeline and the second heat exchange pipeline are both in a spiral shape, heat exchange media are filled in the heat exchange cooler, the first heat exchange pipeline is in contact with the second heat exchange pipeline through the heat exchange media, two ends of the first heat exchange pipeline are respectively communicated with a flue gas inlet and a flue gas outlet of the heat exchange cooler, two ends of the second heat exchange pipeline extend out of the heat exchange cooler and are respectively connected with a gas inlet pipeline and a gas outlet pipeline, a second air pump is installed on the gas inlet pipeline, a third air pump is installed on the gas outlet pipeline, the gas outlet pipeline is connected with a six-way valve, a first gas outlet of the six-way valve is communicated with an auxiliary gas inlet of a rotary kiln through the first conveying pipeline, a second gas outlet of the six-way valve is communicated with an auxiliary gas inlet of a second combustion chamber through the second conveying pipeline, a third gas outlet of the six-way valve is connected with an external hot gas conveying pipeline, and a pressure air pump is installed on the external hot gas conveying pipeline.

Further: the active carbon dust removal and filtration system comprises a mounting frame, a dust removal and filtration box body, an active carbon regeneration box body, a first active carbon storage seat, a first grid plate, a sealing plate, a first electric cylinder, a sealed electric cylinder and a translation trolley, wherein the dust removal and filtration box body is fixed on the mounting frame, the lower end of the dust removal and filtration box body is funnel-shaped, a support column is vertically arranged at the bottom of the mounting frame, the dust removal and filtration box body and the active carbon regeneration box body are connected into a whole up and down, the lower end of the active carbon regeneration box body is also funnel-shaped, the translation trolley is connected on a slide rail in a sliding way, the translation trolley moves to be under a discharge port at the bottom of the active carbon regeneration box body along the slide rail, a sealed switch valve is arranged at the discharge port at the bottom of the active carbon regeneration box body, a flue gas inlet is arranged on the side wall at the upper end of the dust removal and filtration box body, a flue gas outlet is also arranged on the side wall at the lower end of the dust removal and filtration box body, the first activated carbon storage seat is fixed on the inner wall of the dedusting and filtering box body between the flue gas inlet and the flue gas outlet, the bottom of the first activated carbon storage seat is also connected with a first grid plate in a sliding manner, the side wall of the dedusting and filtering box body is provided with a first through groove for the first grid plate to extend out, one end of the first grid plate extends into the first through groove and is connected with a first electric cylinder fixed on the outer wall of the dedusting and filtering box body, the flue gas inlet is connected with a first flue gas conveying pipeline, the flue gas outlet is connected with a second flue gas conveying pipeline, a sealing plate is also movably connected in the dedusting and filtering box body below the flue gas outlet, the dedusting and filtering box body is sealed with the activated carbon regeneration box body through the sealing plate, and the side wall of the dedusting and filtering box body is also provided with a second through groove matched with the sealing plate, one end of the sealing plate extends into the second through groove and is connected with a sealed electric cylinder fixed on the outer wall of the dedusting filter box body.

Further: the activated carbon regeneration box in be fixed with second activated carbon storage seat, the bottom sliding connection of second activated carbon storage seat has the second grid plate, set up the third that is used for the second grid plate to stretch out on the lateral wall of activated carbon regeneration box and lead to the groove, the one end of second grid plate stretches into to the third and leads to the inslot and links to each other with the electronic jar of second of fixing on activated carbon regeneration box outer wall, hot air inlet and cold air import have been seted up on the lateral wall of the activated carbon regeneration box of second activated carbon storage seat top, cold air inlet and cold air inlet link to each other with cold air inlet duct, hot air inlet and hot air inlet duct link to each other, cold air outlet and hot air outlet have been seted up on the lateral wall of the activated carbon regeneration box of second activated carbon storage seat below, cold air outlet and cold air outlet say that the pipeline links to each other, hot air outlet say through giving vent to anger that hot air duct and second flue gas conveying pipeline converge the back together and be linked to each other with the air inlet of second combustion chamber, nitrogen gas import and nitrogen gas import have still been seted up on the lateral wall of the activated carbon regeneration box of cold air outlet and hot air outlet below and nitrogen gas inlet duct, nitrogen inlet and nitrogen inlet duct link to each other.

And further: first active carbon storage seat and second active carbon storage seat in all set up a plurality of storage channels that are used for storing the active carbon that link up from top to bottom, the active carbon in the first active carbon storage seat passes through the restriction of first grid plate in the storage channel of first active carbon storage seat, the active carbon passes through the restriction of second grid plate in the storage channel of second active carbon storage seat in the second active carbon storage seat, the top of dust removal filtration box be provided with the kuppe rather than being linked together, the kuppe rather than the active carbon feed bin directly over be linked together, the active carbon in the first active carbon storage seat fills through the active carbon feed bin.

And further: and a fourth gas outlet of the six-way valve is connected with a gas inlet of the heating device through a third conveying pipeline, a hot gas inlet pipeline is connected with a gas outlet of the heating device, and one end of the third conveying pipeline, which is close to the heating device, is also connected with a hot gas supplementing pipeline.

And further: heating device include heating box, electric heating pipe, first division board and second division board, turn right from a left side and set gradually a plurality of first division boards and second division board in the heating box, crisscross setting with the second division board of a plurality of first division boards, first division board many than the second division board, respectively be provided with an electric heating pipe in the heating box between adjacent first division board and the second division board, the upper end of first division board and front and back outer wall contact with roof in the heating box respectively and front and back inner wall, there is the clearance between the lower extreme of first division board and the bottom in the heating box, the lower extreme of second division board and front and back outer wall contact with bottom in the heating box respectively and front and back inner wall, leave the clearance between the upper end of second division board and the roof in the heating box.

And further: flue gas accelerating device include three flue gas pipeline with higher speed, left supporting disk, right supporting disk, carousel, servo motor and axis of rotation, three flue gas pipeline with higher speed all is the tesla valve pipeline, the carousel be provided with two, three flue gas pipeline with higher speed regular triangle sets up between two carousels, the carousel of both sides is passed respectively at the both ends of flue gas pipeline with higher speed, left side supporting disk and right supporting disk are placed relatively and all offer the circular recess that is used for connecting the carousel in the one side mutually, two carousels rotate respectively and connect in the circular recess of left supporting disk and right supporting disk, servo motor install on the outer wall of left supporting disk and link to each other rather than the axis of rotation, the axis of rotation stretch into in the circular recess of left supporting disk and link to each other with the carousel of connecting in the circular recess of left supporting disk, three flue gas pipeline with higher speed rotates under servo motor's drive along with the carousel, left supporting disk with all be provided with three connection pad in the circular recess of right supporting disk relatively, the center department of connection pad has all seted up the through-hole, three connection pad also is regular triangle and arranges in the same circular recess, flue gas pipeline with higher speed the pipeline in the connection pad in the circular recess of both sides in three connection pad, the top gas pipeline is linked to each other with the third side gas pipeline the top connection pad, the fourth gas pipeline is linked to be linked together with the fourth supporting disk.

And further: the connecting disc of the lowest portion in the left supporting disc is connected with the waste residue collecting box through a backflow pipeline, the connecting disc of the lowest portion in the right supporting disc is connected with the water storage tank through a flushing pipeline, and a liquid pump is installed on the flushing pipeline.

And further: and a fifth gas outlet of the six-way valve is connected with a connecting disc at the middle position in the right supporting disc through a fourth conveying pipeline, the connecting disc at the middle position in the left supporting disc is connected with an exhaust pipeline, and the exhaust pipeline and the second flue gas conveying pipeline are converged and then are communicated with a gas inlet of the secondary combustion chamber.

And further: the both ends of pipeline are all provided with expansion joint with higher speed to the flue gas, expansion joint constitute by fixed part, pars contractilis and spring, the one end of fixed part and flue gas pipeline are even as an organic whole with higher speed, the one end of pars contractilis stretches into to its inside from the other end of fixed part, the pars contractilis stretches into one end in the fixed part and flue gas and is provided with the spring between the pipeline with higher speed, the other end of pars contractilis stretches into to the connection pad in under the effect of spring, the pars contractilis is kept away from and is provided with first conical surface on the outer wall of fixed part one end, all be provided with on the inner wall of connection pad and the outer wall with first conical surface assorted second conical surface, first conical surface contact with the second conical surface on the connection pad inner wall under the effect of spring and seal.

After the structure is adopted, the heat exchange cooler is used for collecting the heat of the flue gas exhausted from the secondary combustion chamber, and the collected heat is conveyed into the rotary kiln and the secondary combustion chamber again through the air, so that the energy loss can be effectively reduced, and the cost is reduced; the temperature of the discharged gas can be reduced, and the adverse effect on the surrounding environment is reduced; and the collected heat can be combined with high-temperature gas and then used active carbon is regenerated through heating, so that the resource is saved.

Drawings

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

FIG. 1 is a schematic structural diagram of the present invention.

Fig. 2 is an internal structural view of the activated carbon dust removal filter system.

Fig. 3 is a schematic structural diagram of a flue gas acceleration device.

Fig. 4 is a schematic structural view of the left support plate.

Fig. 5 is a structural view of the expansion joint.

Fig. 6 is an internal structure view of the heating device.

Fig. 7 is an internal structural view of a flue gas acceleration duct.

Detailed Description

A miniaturized high-concentration contaminated soil ex-situ thermal desorption system as shown in fig. 1, which comprises a rotary kiln 2, a second combustion chamber 4, a dust removal filter, a heat exchange cooler 6 and a desulfurization tower 9, wherein the rotary kiln is a small rotary kiln, the second combustion chamber is a horizontal small second combustion chamber, the dust removal filter consists of an active carbon dust removal filtering system 3 and a bag-type dust remover 8, an air outlet of the rotary kiln is communicated with the active carbon dust removal filtering system through a first flue gas conveying pipeline 11, the active carbon dust removal filtering system is communicated with an air inlet of the second combustion chamber through a second flue gas conveying pipeline 12, an air outlet of the second combustion chamber is communicated with a flue gas accelerating device 5 through a third flue gas conveying pipeline 13, the flue gas accelerating device is communicated with a flue gas inlet of the heat exchange cooler through a fourth flue gas conveying pipeline 14, a flue gas outlet of the heat exchange cooler is communicated with an air inlet of the bag-type dust remover through a fifth flue gas conveying pipeline 15, an air outlet of the bag-type dust remover is communicated with the desulfurization tower through a sixth flue gas conveying pipeline 16, and a sixth flue gas conveying pipeline is provided with a first gas pump 37;

the heat exchange cooler is internally provided with a first heat exchange pipeline and a second heat exchange pipeline which are both in a spiral shape, heat exchange media are filled in the heat exchange cooler, the first heat exchange pipeline is in contact with the second heat exchange pipeline through the heat exchange media, two ends of the first heat exchange pipeline are respectively communicated with a flue gas inlet and a flue gas outlet of the heat exchange cooler, two ends of the second heat exchange pipeline extend out of the heat exchange cooler and are respectively connected with the air inlet pipeline 21 and the air outlet pipeline 22, the air inlet pipeline is provided with a second air pump 38, the air outlet pipeline is provided with a third air pump 40, the air outlet pipeline is connected with a six-way valve 10, a first air outlet of the six-way valve is communicated with an auxiliary air inlet of the rotary kiln through a first conveying pipeline 23, a second air outlet of the six-way valve is communicated with an auxiliary air inlet of a second combustion chamber through a second conveying pipeline 24, a third air outlet of the six-way valve is connected with an external hot air supply pipeline 25, and the external air supply pipeline is provided with a pressure pump 41.

The heat exchange cooler is used for collecting the heat of the flue gas discharged from the secondary combustion chamber, and the collected heat is conveyed into the rotary kiln and the secondary combustion chamber again through the air, so that the energy loss can be effectively reduced, and the cost is reduced; and the temperature of the discharged gas can be reduced, and the adverse effect on the surrounding environment can be reduced.

The active carbon dust removal and filtration system shown in figure 2 comprises a mounting frame 3-3, a dust removal and filtration box body 3-1, an active carbon regeneration box body 3-2, a first active carbon storage seat 3-10, a first grid plate 3-11, a sealing plate 3-14, a first electric cylinder 3-12, a sealed electric cylinder 3-13 and a translation trolley 3-5, wherein the dust removal and filtration box body is fixed on the mounting frame, the lower end of the dust removal and filtration box body is funnel-shaped, a support column 3-7 is vertically arranged at the bottom of the mounting frame, the dust removal and filtration box body and the active carbon regeneration box body are vertically connected into a whole, the lower end of the active carbon regeneration box body is also funnel-shaped, the translation trolley is slidably connected on a slide rail 3-6, the translation trolley moves along the slide rail to be right below a discharge port at the bottom of the active carbon regeneration box body, and a sealed switch valve 3-4 is installed at the discharge port at the bottom of the active carbon regeneration box body, the side wall of the upper end of the dust-removing filtering box body is provided with a flue gas inlet, the side wall of the lower end of the dust-removing filtering box body is also provided with a flue gas outlet, the first activated carbon storage seat is fixed on the inner wall of the dust-removing filtering box body between the flue gas inlet and the flue gas outlet, the bottom of the first activated carbon storage seat is also connected with a first grid plate in a sliding manner, the side wall of the dust-removing filtering box body is provided with a first through groove for the first grid plate to extend out, one end of the first grid plate extends into the first through groove and is connected with a first electric cylinder fixed on the outer wall of the dust-removing filtering box body, the flue gas inlet is connected with a first flue gas conveying pipeline, the flue gas outlet is connected with a second flue gas conveying pipeline, and a sealing plate is movably connected in the dust-removing filtering box body below the flue gas outlet, the dust removal filters the box and seals through closing plate and active carbon regeneration box, also seted up on the lateral wall of dust removal filters the box with closing plate assorted second lead to the groove, the one end of closing plate stretches into to the second and leads to the inslot and links to each other with the sealed electronic jar of fixing on the dust removal filters the box outer wall. The dust removal filter box has the advantages that the dust removal is carried out through the activated carbon in the dust removal filter box body, the activated carbon is replaced and then used continuously after being used for a period of time, the replaced activated carbon falls into the activated carbon regeneration box body to be regenerated and then is collected through the translation trolley to be recycled, and the structure and the mode play a role in saving resources and reducing cost.

As shown in fig. 2, a second activated carbon storage seat 3-17 is fixed in the activated carbon regeneration box body, the bottom of the second activated carbon storage seat is connected with a second grid plate 3-16 in a sliding manner, a third through groove for the second grid plate to extend out is formed in the side wall of the activated carbon regeneration box body, one end of the second grid plate extends into the third through groove and is connected with a second electric cylinder 3-15 fixed on the outer wall of the activated carbon regeneration box body, a hot air inlet and a cold air inlet are formed in the side wall of the activated carbon regeneration box body above the second activated carbon storage seat, the cold air inlet is connected with a cold air inlet 33, the hot air inlet is connected with a hot air inlet pipeline 31, a cold air outlet and a hot air outlet are formed in the side wall of the activated carbon regeneration box body below the second activated carbon storage seat, the cold air outlet is connected with a cold air outlet pipeline 32, the hot air outlet is converged with a second flue gas conveying pipeline 34 through a hot air outlet and is connected with an air inlet of a second combustion chamber, the hot air outlet and the activated carbon regeneration box body below the hot air outlet are also formed in a side wall of the activated carbon regeneration box body, the ammonia inlet and an ammonia inlet are connected with a nitrogen inlet, and an ammonia inlet 36, and an ammonia inlet is connected with a nitrogen regeneration structure, and an ammonia inlet of the activated carbon regeneration box body, and an ammonia inlet is connected with a nitrogen regeneration device.

As shown in fig. 2, a plurality of vertically-through storage channels for storing activated carbon are arranged in the first activated carbon storage seat and the second activated carbon storage seat, the activated carbon in the first activated carbon storage seat is limited in the storage channel of the first activated carbon storage seat through a first grid plate, the activated carbon in the second activated carbon storage seat is limited in the storage channel of the second activated carbon storage seat through a second grid plate, the top of the dedusting filter box body is provided with a flow guide cover 3-9 communicated with the dedusting filter box body, the flow guide cover is communicated with an activated carbon bin 3-8 right above the flow guide cover, and the activated carbon in the first activated carbon storage seat is filled through the activated carbon bin.

The fourth outlet of the six-way valve shown in fig. 1 is connected to the inlet of a heating device 29 via a third delivery conduit 26, the hot gas inlet conduit is connected to the outlet of the heating device, and a hot gas supply conduit 30 is connected to the end of the heating device adjacent to the third delivery conduit. The invention can also combine the collected heat with high-temperature gas and then heat the gas to regenerate the used active carbon, thereby saving resources.

The heating device shown in fig. 6 comprises a heating box body 29-1, electric heating pipes 29-4, a first partition plate 29-2 and a second partition plate 29-3, wherein a plurality of first partition plates and a plurality of second partition plates are sequentially arranged in the heating box body from left to right, the first partition plates and the second partition plates are arranged in a staggered manner, the first partition plates are more than the second partition plates, electric heating pipes are respectively arranged in the heating box body between the adjacent first partition plates and the second partition plates, the upper end and the front and rear outer walls of the first partition plates are respectively contacted with the top wall and the front and rear inner walls in the heating box body, gaps are reserved between the lower end of the first partition plate and the bottom in the heating box body, the lower end and the front and rear outer walls of the second partition plate are respectively contacted with the bottom and the front and rear inner walls in the heating box body, and gaps are reserved between the upper end of the second partition plate and the top wall in the heating box body. The invention prolongs the mixing and heating time of the gas by adopting the structure.

The flue gas accelerating device shown in the figures 3, 4 and 7 comprises three flue gas accelerating pipelines 5-1, a left supporting disk 5-2, a right supporting disk 5-3, a rotating disk 5-4, a servo motor 5-5 and a rotating shaft 5-6, wherein the three flue gas accelerating pipelines are all Tesla valve pipelines, the rotating disks are provided with two blocks, three flue gas accelerating pipeline regular triangles are arranged between the two rotating disks, two ends of the flue gas accelerating pipelines respectively penetrate through the rotating disks on two sides, the left supporting disk and the right supporting disk are oppositely arranged and are provided with circular grooves used for being connected with the rotating disks on one sides, the two rotating disks are respectively and rotatably connected in the circular grooves of the left supporting disk and the right supporting disk, the servo motor is arranged on the outer wall of the left supporting disk and is connected with the rotating shaft of the servo motor, the rotating shaft extends into the circular groove of the left supporting disk and is connected with the circular groove disk connected on the left supporting disk, the three flue gas accelerating pipelines rotate under the driving of the servo motor along with the rotating disks, the three connecting disks 5-7 are oppositely arranged in the circular grooves, the center of the connecting disk 5-8 is arranged in the same through hole, the connecting disk, the three flue gas accelerating pipeline regular triangle pipes are connected with the three triangular grooves in the circular groove of the left supporting disk, and connected with the flue gas conveying pipeline in the circular groove in the flue gas accelerating pipeline. The invention plays a role of driving the turntable to rotate by the servo motor after one flue gas acceleration pipeline is used for a period of time, so that the other flue gas acceleration pipeline is used for continuously supplying gas, unnecessary loss caused by blockage of the flue gas acceleration pipeline is prevented, and the flue gas acceleration pipeline is a Tesla valve pipeline, and the heat loss of the flue gas in the conveying process is reduced by the unidirectional acceleration conduction of the Tesla valve pipeline.

As shown in fig. 1, the lowest connecting disc in the left supporting disc is connected with the waste residue collecting tank 18 through a return pipeline 20, the lowest connecting disc in the right supporting disc is connected with the water storage tank 17 through a flushing pipeline 19, and a liquid pump 39 is installed on the flushing pipeline. The structure can be adopted to flush the used flue gas acceleration pipeline, so that the blockage is prevented.

The fifth air outlet of the six-way valve shown in fig. 1 is connected with the connecting disc at the middle position in the right supporting disc through a fourth conveying pipeline 27, the connecting disc at the middle position in the left supporting disc is connected with an exhaust pipeline 28, and the exhaust pipeline and the second flue gas conveying pipeline are converged and then are communicated with the air inlet of the secondary combustion chamber. According to the invention, the washed flue gas acceleration pipeline can be dried by using the collected heat, and the flowing time of the gas with heat in the flue gas acceleration pipeline is prolonged by using the characteristic of the other obstruction of the Tesla valve pipeline, so that the flue gas acceleration pipeline is ensured to be dried.

Both ends of flue gas acceleration pipe as shown in fig. 5 all are provided with expansion joint, expansion joint constitute by fixed part 5-9, pars contractilis 5-10 and spring 5-11, the one end of fixed part and flue gas acceleration pipe are linked together, the other end of fixed part is followed to the one end of pars contractilis and stretches into to inside it, the one end that the pars contractilis stretched into in the fixed part is provided with the spring with higher speed with the flue gas between the pipeline with higher speed with the flue gas, the other end of pars contractilis stretches into to the connection pad in under the effect of spring, the pars contractilis is kept away from and is provided with first conical surface on the outer wall of fixed part one end, all be provided with on the inner wall of connection pad and the outer wall with first conical surface assorted second conical surface, first conical surface contact with the second conical surface on the connection pad inner wall under the effect of spring and seal.

In light of the foregoing description of the preferred embodiment of the present invention, many modifications and variations will be apparent to those skilled in the art without departing from the spirit and scope of the invention. The technical scope of the present invention is not limited to the content of the specification, and must be determined according to the scope of the claims.

Claims

1. The utility model provides a miniaturized high concentration pollutes soil dystopy thermal desorption system, includes rotary kiln (2), second combustion chamber (4), dust removal filter, heat transfer cooler (6) and desulfurizing tower (9), its characterized in that: the rotary kiln is a small rotary kiln, the second combustion chamber is a horizontal small second combustion chamber, the dust removal filter consists of an active carbon dust removal filter system (3) and a bag-type dust remover (8), a gas outlet of the rotary kiln is communicated with the active carbon dust removal filter system through a first flue gas conveying pipeline (11), the active carbon dust removal filter system is communicated with a gas inlet of the second combustion chamber through a second flue gas conveying pipeline (12), a gas outlet of the second combustion chamber is communicated with a flue gas accelerating device (5) through a third flue gas conveying pipeline (13), the flue gas accelerating device is communicated with a flue gas inlet of a heat exchange cooler through a fourth flue gas conveying pipeline (14), a flue gas outlet of the heat exchange cooler is communicated with a gas inlet of the bag-type dust remover through a fifth flue gas conveying pipeline (15), a gas outlet of the bag-type dust remover is communicated with a desulfurization tower through a sixth flue gas conveying pipeline (16), and a first air pump (37) is installed on the sixth flue gas conveying pipeline;

a first heat exchange pipeline and a second heat exchange pipeline are arranged in the heat exchange cooler, the first heat exchange pipeline and the second heat exchange pipeline are both in a spiral shape, heat exchange media are filled in the heat exchange cooler, the first heat exchange pipeline is contacted with the second heat exchange pipeline through the heat exchange media, two ends of the first heat exchange pipeline are respectively communicated with a flue gas inlet and a flue gas outlet of the heat exchange cooler, two ends of the second heat exchange pipeline extend out of the heat exchange cooler and are respectively connected with a gas inlet pipeline (21) and a gas outlet pipeline (22), a second air pump (38) is installed on the gas inlet pipeline, a third air pump (40) is installed on the gas outlet pipeline, the gas outlet pipeline is connected with a six-way valve (10), a first gas outlet of the six-way valve is communicated with an auxiliary gas inlet of the rotary kiln through a first conveying pipeline (23), a second gas outlet of the six-way valve is communicated with an auxiliary gas inlet of a second combustion chamber through a second conveying pipeline (24), a third gas outlet of the six-way valve is connected with a hot gas outer conveying pipeline (25), and a hot gas pump (41) is installed on the outer hot gas pipeline;

the flue gas accelerating device comprises three flue gas accelerating pipelines (5-1), a left supporting disk (5-2), a right supporting disk (5-3), a turntable (5-4), a servo motor (5-5) and a rotating shaft (5-6), wherein the three flue gas accelerating pipelines are all Tesla valve pipelines, the two turntables are arranged, the regular triangle of the three flue gas accelerating pipelines is arranged between the two turntables, two ends of the flue gas acceleration pipeline respectively penetrate through the turntables at two sides, the left supporting disk and the right supporting disk are oppositely arranged, and one surfaces of the left supporting disk and the right supporting disk which are mutually opposite are provided with circular grooves for connecting the turntables, the two turntables are respectively and rotationally connected in the circular grooves of the left supporting disk and the right supporting disk, the servo motor is arranged on the outer wall of the left supporting disk and connected with a rotating shaft of the left supporting disk, the rotating shaft extends into the circular groove of the left supporting disk and is connected with a rotary disk connected in the circular groove of the left supporting disk, the three flue gas accelerating pipelines rotate under the driving of the servo motor along with the rotary disk, three connecting discs (5-7) are oppositely arranged in the circular grooves of the left supporting disc and the right supporting disc, the centers of the connecting discs are provided with through holes (5-8), the three connecting discs in the same circular groove are also arranged in a regular triangle, the flue gas accelerating pipeline is sequentially connected with the three connecting discs in the circular grooves at the two sides along with the rotation, the uppermost connecting disc in the left supporting disc is communicated with a third flue gas conveying pipeline, and the uppermost connecting disc in the right supporting disc is communicated with a fourth flue gas conveying pipeline;

the lowest connecting disc in the left supporting disc is connected with a waste residue collecting box (18) through a return pipe (20), the lowest connecting disc in the right supporting disc is connected with a water storage tank (17) through a flushing pipe (19), and a liquid pump (39) is installed on the flushing pipe;

a fifth air outlet of the six-way valve is connected with a connecting disc positioned at the middle position in the right supporting disc through a fourth conveying pipeline (27), the connecting disc positioned at the middle position in the left supporting disc is connected with an exhaust pipeline (28), and the exhaust pipeline and a second flue gas conveying pipeline are converged and then are communicated with an air inlet of a secondary combustion chamber;

the both ends of pipeline are all provided with expansion joint with higher speed to the flue gas, expansion joint constitute by fixed part (5-9), pars contractilis (5-10) and spring (5-11), the one end of fixed part and flue gas pipeline are even integrative with higher speed, the one end of pars contractilis stretches into to its inside from the other end of fixed part, the pars contractilis stretches into one end in the fixed part and flue gas and is provided with the spring between the pipeline with higher speed, the other end of pars contractilis stretches into to the connection pad under the effect of spring in, the pars contractilis is kept away from and is provided with first conical surface on the outer wall of fixed part one end, all be provided with on the inner wall of connection pad and the outer wall with first conical surface assorted second conical surface, first conical surface contact with the second conical surface on the connection pad inner wall and seal under the effect of spring.

2. The system of claim 1, wherein the system is characterized in that: the active carbon dust removal and filtration system comprises an installation frame (3-3), a dust removal and filtration box body (3-1), an active carbon regeneration box body (3-2), a first active carbon storage seat (3-10), a first grid plate (3-11), a sealing plate (3-14), a first electric cylinder (3-12), a sealed electric cylinder (3-13) and a translation trolley (3-5), wherein the dust removal and filtration box body is fixed on the installation frame, the lower end of the dust removal and filtration box body is funnel-shaped, a support column (3-7) is vertically arranged at the bottom of the installation frame, the dust removal and filtration box body and the active carbon regeneration box body are connected into a whole from top to bottom, the lower end of the active carbon regeneration box body is also funnel-shaped, the translation trolley is connected on a slide rail (3-6) in a sliding manner, the translation trolley moves to the position under a discharge port at the bottom of the active carbon regeneration box body along the slide rail, a sealing switch valve (3-4) is installed at a discharge port at the bottom of the activated carbon regeneration box, a flue gas inlet is formed in the side wall at the upper end of the dedusting and filtering box body, a flue gas outlet is also formed in the side wall at the lower end of the dedusting and filtering box body, the first activated carbon storage seat is fixed on the inner wall of the dedusting and filtering box body between the flue gas inlet and the flue gas outlet, a first grid plate is connected to the bottom of the first activated carbon storage seat in a sliding manner, a first through groove for extending the first grid plate is formed in the side wall of the dedusting and filtering box body, one end of the first grid plate extends into the first through groove and is connected with a first electric cylinder fixed on the outer wall of the dedusting and filtering box body, the flue gas import link to each other with first flue gas pipeline, the exhanst gas export link to each other with second flue gas pipeline, the dust removal filter box body of exhanst gas export below is internal still swing joint has the closing plate, the dust removal filter box body seal with the active carbon regeneration box through the closing plate, also seted up on the lateral wall of dust removal filter box body and led to the groove with closing plate assorted second, the one end of closing plate stretches into to the second and leads to the inslot and links to each other with the sealed electronic jar of fixing on the dust removal filter box body outer wall.

3. The system of claim 2, wherein the system is characterized in that: the activated carbon regeneration box in be fixed with second activated carbon storage seat (3-17), the bottom sliding connection of second activated carbon storage seat has second grid plate (3-16), set up the third logical groove that is used for the second grid plate to stretch out on the lateral wall of activated carbon regeneration box, the one end of second grid plate stretches into to the third logical inslot and links to each other with second electronic jar (3-15) of fixing on activated carbon regeneration box outer wall, hot air inlet and cold wind import have been seted up on the lateral wall of the activated carbon regeneration box of second activated carbon storage seat top, cold wind import and cold wind inlet duct (33) link to each other, hot air inlet and hot gas inlet pipeline (31) link to each other, cold air outlet and hot gas outlet have been seted up on the lateral wall of the activated carbon regeneration box of second activated carbon storage seat below, cold wind export link to each other with cold wind pipeline (32), hot gas outlet through hot gas outlet pipeline (34) and second flue gas conveying pipeline after converging together be linked to each other with the air inlet of second combustion chamber, hot gas outlet and the activated carbon regeneration box below set up on the ammonia inlet and the nitrogen gas inlet (36) and the nitrogen gas inlet of ammonia pipeline (36) link to each other.

4. The system of claim 3, wherein the system is characterized in that: first active carbon storage seat and second active carbon storage seat in all seted up a plurality of storage passageway that are used for storing the active carbon that link up from top to bottom, the active carbon in the first active carbon storage seat passes through first grid plate restriction in the storage passageway of first active carbon storage seat, the active carbon passes through the restriction of second grid plate in the storage passageway of second active carbon storage seat in the second active carbon storage seat, the top of dust removal filtration box be provided with kuppe (3-9) rather than being linked together, the kuppe rather than active carbon feed bin (3-8) directly over be linked together, the active carbon in the first active carbon storage seat fills through the active carbon feed bin.

5. The system of claim 3, wherein the system is characterized in that: and a fourth air outlet of the six-way valve is connected with an air inlet of a heating device (29) through a third conveying pipeline (26), a hot air inlet pipeline is connected with an air outlet of the heating device, and one end of the third conveying pipeline, close to the heating device, is also connected with a hot air supplementing pipeline (30).

6. The system of claim 5, wherein the system is characterized in that: heating device include heating box (29-1), electric heating pipe (29-4), first division board (29-2) and second division board (29-3), turn right from a left side in the heating box and set gradually a plurality of first division boards and second division board, the crisscross setting of a plurality of first division boards and second division board, first division board many than the second division board, respectively be provided with an electric heating pipe in the heating box between adjacent first division board and the second division board, the upper end of first division board and outer wall contact with roof in the heating box respectively around and, have the clearance between the lower extreme of first division board and the bottom in the heating box, the lower extreme of second division board and outer wall contact with the bottom in the heating box respectively around and, leave the clearance between the upper end of second division board and the roof in the heating box.