CN112915700A

CN112915700A - High-temperature waste gas purifying equipment

Info

Publication number: CN112915700A
Application number: CN202110085494.8A
Authority: CN
Inventors: 费红泉
Original assignee: Individual
Current assignee: Individual
Priority date: 2021-01-22
Filing date: 2021-01-22
Publication date: 2021-06-08

Abstract

The invention discloses a high-temperature waste gas purification device, which structurally comprises a discharge cavity, a fan, an inlet and an outlet, a removal device, a purification cavity and a machine body.

Description

High-temperature waste gas purifying equipment

Technical Field

The invention relates to the field of exhaust emission, in particular to high-temperature exhaust gas purification equipment.

Background

The waste gas refers to poisonous and harmful gas discharged by human in the production and living process, especially chemical plant, steel plant, pharmaceutical factory, coking plant and oil refinery, etc., the waste gas generally has the characteristics of flammability, easy explosion, poison, no water, solubility in organic solvent, great processing difficulty, etc., the harmful substance in the waste gas is removed by the removing element, when purifying the high-temperature waste gas, the place needing to be improved is:

when purifying high temperature waste gas, convey the inside reaction treatment that carries out of process chamber with waste gas, in the processing procedure, because contain a large amount of sulfur dioxide in the industrial waste gas, equipment can't carry out abundant absorption treatment with the sulfur dioxide in the waste gas, if directly discharge waste gas to the air in, the sulfur dioxide of remaining in the waste gas can spread in the air thereupon, can make atmospheric temperature promote, cause more serious environmental pollution, and the dust impurity that produces behind the exhaust-gas treatment can pile up inside equipment, because the dust receives can contain higher humidity under the high temperature effect of waste gas, lead to the dust can the adhesion inside equipment, lead to the inside easy peculiar smell that produces of equipment, need staff secondary treatment, reduce the treatment effeciency of waste gas and the result of use of equipment.

Disclosure of Invention

Aiming at the defects in the prior art, the invention is realized by the following technical scheme: the utility model provides a high temperature exhaust gas purification equipment, its structure is including discharging chamber, fan, exit, remove device, purification chamber, organism, it establishes in the bottom of the body to discharge the chamber, the organism is kept away from the one end that discharges the chamber and establishes and is put through mutually with remove device, remove device all is equipped with exit with the one end that discharges the chamber and keep away from the organism, the purification chamber is installed to the organism intermediate position, it is connected with the fan to purify chamber one side, the fan passes through electric wire connection with the organism.

As a further optimization of the invention, the removing device comprises a sulfur removing component, a partition plate, an adsorption groove, a connector, a receiving cavity and a body, wherein the sulfur removing component is arranged at the bottom of the body, the sulfur removing component is provided with the adsorption groove communicated with the sulfur removing component, the partition plate is arranged on each of two sides of the adsorption groove, one end, far away from the adsorption groove, of each partition plate is tightly attached to the body, the adsorption groove is communicated with the receiving cavity, the connector is arranged in the middle of the top of the receiving cavity and communicated with the inlet and the outlet, and the sulfur removing component is communicated with the purifying cavity through a machine body.

As a further optimization of the invention, the desulfurization component comprises a floating rod, a cavity, a processing piece, a pulling strip, a clamping plate and guide plates, wherein the floating rod penetrates through the guide plates and is connected with the pulling strip, one end of the pulling strip, which is far away from the floating rod, is attached to the processing piece, five guide plates are arranged on the clamping plate in parallel at equal intervals, the guide plates are fixedly connected with the processing piece, the processing piece is arranged on the cavity in parallel, the cavity is connected with the clamping plate, the cavity is arranged at the bottom of the body, the processing piece is communicated with the adsorption tank, and the guide plates are communicated with the purification cavity through the machine body.

As the further optimization of the invention, the treatment part comprises a circulation plate, a molecular sieve layer, a dispersion part, an inclined guide plate, a reaction membrane and a propping part, wherein the circulation plate is arranged at the bottom of the molecular sieve layer, the propping part connected with the circulation plate is arranged in the middle of the interior of the molecular sieve layer, one end of the molecular sieve layer far away from the circulation plate is connected with the reaction membrane, the reaction membrane is communicated with the dispersion part, the inclined guide plate buckled with the dispersion part is arranged at both ends of the dispersion part far away from the reaction membrane, the circulation plate is jointed with the pull strip, the guide plate is communicated with the circulation plate, the inclined guide plate is arranged on the cavity, and the inclined guide plate is communicated with the adsorption tank.

The top support part comprises four connecting pieces, springs, connecting buckles and a shell, wherein the four connecting pieces are symmetrically connected inside the shell, two ends of each connecting piece are attached to two sides of the inner wall of the shell, the springs connected with the two connecting pieces are arranged between the two connecting pieces, the connecting buckles are mounted at two ends of the shell and are buckled inside the molecular sieve layer.

As the further optimization of the invention, the dispersion part comprises an adhesion net, a plurality of separation rods and a guide interface, wherein the adhesion net is connected with the separation rods, the adhesion net and the separation rods are arranged in plurality, the adhesion net and the separation rods are connected on the guide interface in an annular mode at equal intervals, the adhesion net is communicated with the reaction membrane, and the guide interface is connected with the inclined guide plate.

As a further optimization of the invention, the adsorption groove comprises a flow guide cavity, an adsorption separation net, a flow guide port, a sliding arc plate and an auxiliary part, wherein the two sides of the flow guide cavity are respectively provided with the sliding arc plate which is attached to the flow guide cavity, one end of the sliding arc plate, far away from the flow guide cavity, is connected with the side wall of the flow guide port, the adsorption separation net is arranged on the flow guide port, the two ends of the adsorption separation net are buckled on the two sliding arc plates, the auxiliary part is arranged on one end of the adsorption separation net, far away from the flow guide port, and is installed on the flow guide cavity, the flow guide port is communicated with the inclined guide plate, the sliding arc plate is attached to the partition plate, and the flow guide cavity is communicated with.

As a further optimization of the invention, the auxiliary part comprises an air bag, a filtering cone, a fine filter screen and an air connecting port, two air connecting ports are arranged in the middle of the air bag, the outer wall of the air bag is connected with the fine filter screen, the filtering cone is arranged at one end of the fine filter screen, which is far away from the air bag, the fine filter screen is arranged on the adsorption filtering screen, and the air bag is arranged on the flow guide cavity.

As the content of the invention is further optimized, the filter cone comprises two rubber arc blocks, a triangular spine, a positioning shaft, a patch, a folding sheet and a limiting block, wherein the two rubber arc blocks are symmetrically attached to two sides of the triangular spine, one end of each rubber arc block, far away from the triangular spine, is provided with the patch connected with the triangular spine, the folding sheet is arranged inside the triangular spine, the positioning shaft is arranged in the middle of the folding sheet and is buckled with the limiting block, the folding sheet is connected with the limiting block through the positioning shaft, the bottom of the limiting block is connected with the triangular spine, and the triangular spine is arranged on the fine filter screen.

Advantageous effects

The high-temperature waste gas purification equipment provided by the invention has the following beneficial effects:

1. according to the invention, through the combined arrangement of the floating rod, the traction strip and the guide plate, gas flows into the guide plate, the guide plate is of a conical structure with a large upper part and a small lower part, the downward flow guide of the gas is limited and extruded, so that the floating rod can be popped downwards under the action of the gas, the gas is effectively led outwards, and the floating rod can be ensured to stably float upwards and downwards through the cooperation of the traction strip and the movable traction of the floating rod.

2. According to the invention, through the combination arrangement of the adhesion net, the separation rod and the guide port, gas flows down from the guide port, the gas can directly contact the adhesion net, the surface of the adhesion net has certain viscosity, and the separation rod separates the adhesion net into a plurality of pieces, so that dust in the flying gas can be effectively adsorbed.

3. According to the invention, through the combined arrangement of the air bag, the filtering cones, the fine filter screen and the air connecting ports, the downward flow of the gas can directly contact with the filtering cones, the gas can flow downward to the fine filter screen in the treatment process, the fine filter screen assists the plurality of filtering cones to simultaneously treat the waste gas, the gas can flow downward to the inside of the air bag through the air connecting ports, the inside of the air bag is inflated and expanded, the volume of the fine filter screen is effectively expanded, and the waste gas is effectively treated.

Drawings

Other features, objects and advantages of the invention will become more apparent upon reading of the detailed description of non-limiting embodiments with reference to the following drawings:

FIG. 1 is a schematic structural view of a high-temperature exhaust gas purifying apparatus according to the present invention;

FIG. 2 is a schematic plan view of the removing device of the present invention.

FIG. 3 is a schematic cross-sectional view of a desulfurization module in accordance with the present invention.

FIG. 4 is a schematic view of the internal structure of the treating member of the present invention.

FIG. 5 is a schematic view of the internal structure of the top support member of the present invention.

Fig. 6 is a schematic bottom view of the dispersing element of the present invention.

FIG. 7 is a schematic view of the internal structure of the adsorption tank of the present invention.

Fig. 8 is a schematic cross-sectional view of the auxiliary member of the present invention.

FIG. 9 is a schematic view of the internal structure of the isolation cone of the present invention.

In the figure: the device comprises a discharge cavity 1, a fan 2, an inlet/outlet 3, a removing device 4, a purification cavity 5, a machine body 6, a sulfur removal assembly 41, a partition plate 42, an adsorption groove 43, an interface 44, a receiving cavity 45, a body 46, a floating rod 411, a cavity 412, a treatment member 413, a pulling strip 414, a clamping plate 415, a guide plate 416, a flow-through plate 131, a molecular sieve layer 132, a dispersing member 133, a slant guide plate 134, a reaction membrane 135, a top support member 136, a connecting piece C1, a spring C2, a connecting buckle C3, a shell C4, an adhesive net D1, a separating rod D2, a guide interface D3, a guide cavity 431, an adsorption net 432, a guide opening 433, a sliding arc plate 434, an auxiliary member 435, an air bag 351, a filter cone 352, a fine filter screen 353, an air connecting opening 354, a rubber arc block E1, a triangular thorn E2, a positioning shaft E3, a patch E4, a opening and a limiting block E.

Detailed Description

In order to make the technical means, the creation characteristics, the achievement purposes and the effects of the invention easy to understand, the invention is further described with the specific embodiments.

Example one

Referring to fig. 1, the present invention provides a technical solution: the utility model provides a high temperature exhaust gas purification equipment, its structure is including discharging chamber 1, fan 2, importing and exporting 3, remove device 4, purifying chamber 5, organism 6, it establishes in 6 bottoms of organism to discharge chamber 1, organism 6 is kept away from the one end that discharges chamber 1 and establish and is put through mutually with remove device 4, remove device 4 all is equipped with importing and exporting 3 with the one end that discharges chamber 1 and keep away from

organism

6, 6 intermediate positions of organism are installed and are purified chamber 5, it is connected with fan 2 to purify 5 one side in chamber, fan 2 passes through electric wire connection with organism 6.

Referring to fig. 2, the removing device 4 includes a sulfur removing assembly 41, a partition plate 42, an adsorption tank 43, a connector 44, a receiving cavity 45, and a body 46, the sulfur removing assembly 41 is disposed at the bottom of the body 46, the adsorption tank 43 connected to the sulfur removing assembly 41 is disposed on the sulfur removing assembly 41, the partition plate 42 is disposed on each of two sides of the adsorption tank 43, one end of the partition plate 42 away from the adsorption tank 43 is tightly attached to the body 46, the adsorption tank 43 is connected to the receiving cavity 45, the connector 44 is disposed at the middle position of the top of the receiving cavity 45, the connector 44 is connected to the inlet/outlet 3, and the sulfur removing assembly 41 is connected to the purifying cavity 5 through the body 6.

Referring to fig. 3, the desulfurization module 41 includes a floating rod 411, a cavity 412, a processing member 413, a pulling bar 414, a clamping plate 415, and five flow deflectors 416, the floating rod 411 is connected to the pulling bar 414 through the flow deflector 416, one end of the pulling bar 414 away from the floating rod 411 is attached to the processing member 413, the five flow deflectors 416 are arranged on the clamping plate 415 in parallel and at equal intervals, the flow deflectors 416 are fixedly connected to the processing member 413, the processing member 413 is mounted in parallel on the cavity 412, the cavity 412 is connected to the clamping plate 415, the cavity 412 is arranged at the bottom of the body 46, the processing member 413 is connected to the adsorption tank 43, and the flow deflectors 416 are connected to the purification chamber 5 through the body 6.

The pulling strip 414 is used for pulling the floating rod 411, the floating rod 411 can move downwards under the action of air, the air is effectively discharged outwards, the pulling strip 414 is used for pulling the floating rod 411, and the floating rod 411 is prevented from separating from the guide plate 416 after moving downwards.

Referring to fig. 4, the treating member 413 includes a circulation plate 131, a molecular sieve layer 132, a dispersion member 133, an inclined guide plate 134, a reaction membrane 135, and a top support member 136, the circulation plate 131 is disposed at the bottom of the molecular sieve layer 132, the top support member 136 connected to the circulation plate 132 is disposed at the middle position inside the molecular sieve layer 132, one end of the molecular sieve layer 132 away from the circulation plate 131 is connected to the reaction membrane 135, the reaction membrane 135 is communicated with the dispersion member 133, the inclined guide plate 134 fastened to both ends of the dispersion member 133 away from the reaction membrane 135 are disposed at both ends of the circulation plate 131, the circulation plate 131 is attached to a brace 414, the guide plate 416 is communicated with the circulation plate 131, the inclined guide plate 134 is mounted on the cavity 412, and the inclined guide plate 134 is communicated with the adsorption tank 43.

The inclined guide plates 134 are used for matching with the dispersion member 133, and the two inclined guide plates 134 are in an inclined state, so that the gas can slide downwards due to inertia, and the waste gas is effectively guided downwards into the dispersion member 133.

Referring to fig. 5, the top supporting member 136 includes four connecting pieces C1, a spring C2, a buckle C3, and a housing C4, where the four connecting pieces C1 are symmetrically connected inside the housing C4, two ends of the connecting piece C1 are both attached to two sides of the inner wall of the housing C4, a spring C2 connected to the two connecting pieces C1 is disposed between the two connecting pieces C1, two ends of the housing C4 are provided with buckles C3, and the buckle C3 is buckled inside the molecular sieve layer 132.

The spring C2 is used to cooperate with the housing C4, and the housing C4 retracts inward after receiving the air pressure conducted downward by the molecular sieve layer 132, and is supported by the spring C2, so as to ensure that the molecular sieve layer 132 can be stably processed.

Referring to fig. 6, the dispersing member 133 includes an adhesive net D1, a separating rod D2, and a guide port D3, the adhesive net D1 is connected to the separating rod D2, a plurality of adhesive nets D1 and separating rods D2 are provided, a plurality of adhesive nets D1 and separating rods D2 are connected to the guide port D3 in an equidistant ring shape, the adhesive net D1 is communicated with the reaction membrane 135, and the guide port D3 is connected to the inclined guide plate 134.

The separating rod D2 is used to cooperate with the adhesive net D1, and the adhesive net D1 is equally divided into a plurality of pieces by the separating rod D2, so that the plurality of adhesive nets D1 can simultaneously and rapidly treat the dust in the exhaust gas.

Example two

organism

Referring to fig. 7, the adsorption groove 43 includes a flow guide cavity 431, an adsorption screen 432, a flow guide port 433, an arc sliding plate 434, and an auxiliary member 435, the two sides of the flow guide cavity 431 are respectively provided with the arc sliding plate 434 attached to the flow guide cavity 431, one end of the arc sliding plate 434 away from the flow guide cavity 431 is connected to the side wall of the flow guide port 433, the adsorption screen 432 is provided on the flow guide port 433, the two ends of the adsorption screen 432 are fastened to the two arc sliding plates 434, one end of the adsorption screen 432 away from the flow guide port 433 is provided with the auxiliary member 435, the auxiliary member 435 is installed on the flow guide cavity 431, the flow guide port 433 is connected to the inclined guide plate 134, the arc sliding plate 434 is attached to the partition plate 42, and the flow guide cavity 431 is connected to the receiving cavity 45.

The sliding arc plate 434 is used for matching with the flow guide cavity 431, the sliding arc plate 434 is in an inclined arc plate shape, and the sliding arc plate 434 has a bionic lotus effect and is non-sticky, so that dust impurities in the gas are not easily adhered to the flow guide cavity 431.

Referring to fig. 8, the auxiliary member 435 includes an air bag 351, a filter cone 352, a fine filter screen 353, and an air receiving port 354, two air receiving ports 354 are disposed at the middle position of the air bag 351, the outer wall of the air bag 351 is connected to the fine filter screen 353, the filter cone 352 is mounted at one end of the fine filter screen 353 away from the air bag 351, the fine filter screen 353 is disposed on an adsorption filter screen 432, and the air bag 351 is mounted on the flow guide chamber 431.

The air receiving port 354 is used for being matched with the air bag 351, air flows downwards to the air receiving port 354 through the fine filter screen 353, the air receiving port 354 is of a funnel-shaped structure, the treated air is effectively guided to the air bag 351 through the air receiving port 354, the air bag 351 is inflated to expand, the area of the fine filter screen 353 can be enlarged, and efficient treatment can be effectively carried out on waste gas.

Referring to fig. 9, the filtering cone 352 includes two rubber arc blocks E1, a triangular spine E2, a positioning shaft E3, a patch E4, an opening and closing piece E5, and a stopper E6, the two rubber arc blocks E1 are symmetrically attached to two sides of the triangular spine E2, one end of the rubber arc block E1 away from the triangular spine E2 is provided with a patch E4 connected to the rubber arc block E4, an opening and closing piece E5 is arranged inside the triangular spine E2, the middle position of the opening and closing piece E5 is provided with a positioning shaft E3, the positioning shaft E3 is fastened to the stopper E6, the opening and closing piece E5 is connected to the stopper E6 through the positioning shaft E3, the bottom of the stopper E6 is connected to the triangular spine E2, and the triangular spine E2 is installed on the fine filter screen 353.

The patch E4 is used for being matched with the rubber arc block E1, and the patch E4 and the rubber arc block E1 both have certain viscosity, and effectively adsorb impurities in waste gas after contacting the waste gas.

The working principle of the above technical solution is explained as follows:

when the device is used, the fan 2 is driven, the waste gas is conveyed into the removing device 4 through the inlet and the outlet 3, the sulfur dioxide and the dust in the gas are treated through the removing device 4, the treated waste gas can downwards flow into the purifying cavity 5, the waste gas is efficiently treated through the purifying cavity 5, the treated dust is discharged through the discharging cavity 1, and the discharging efficiency of the waste gas is effectively improved.

When high-temperature waste gas is purified, the interface 44 is communicated with the inlet and outlet 3, the waste gas is conveyed downwards into the receiving cavity 45 through the matching of the inlet and outlet 3 and the interface 44, the receiving cavity 45 receives a large amount of waste gas, the waste gas in the receiving cavity 45 can flow downwards into the flow guide cavity 431 due to inertia, the gas can contact the rubber arc block E1 and the patch E4, the rubber arc block E1 and the patch E4 have certain adhesion, part of dust in the waste gas can be effectively adhered, the waste gas can flow downwards onto the fine filter screen 353 due to the triangular structure of the triangular thorn E2, the fine filter screen 353 performs fine filtering treatment on the waste gas, the treated waste gas can flow downwards into the air bag 351 through the air connecting port 354, the interior of the air bag 351 can expand to expand outwards along with the change of the air bag 351, the limiting block E6 can receive the tension of the fine filter screen to upwards push the opening and closing sheet E5, open and shut piece E5 can expand thereupon, can upwards push away triangular thorn E2, effectively enlarge triangular thorn E2's area, rubber arc piece E1 and paster E4 also can open thereupon, make rubber arc piece E1 and paster E4 can effectively assist fine filter screen 353 to handle the impurity dust in the waste gas, waste gas after the processing can be because inertia landing downwards to adsorb on separating net 432, separate net 432 through multilayer absorption and carry out high-efficient processing to the waste gas after the preliminary treatment, carry out effective processing with the dust impurity in the waste gas, the waste gas after will handling passes through water conservancy diversion mouth 433 and outwards derives, make the dust be difficult for can the adhesion inside equipment, need not staff's secondary treatment, improve equipment's result of use.

Dust in the waste gas is handling the back, waste gas can flow to on the dispersion piece 133 through water conservancy diversion mouth 433, supplementary waste gas leads downwards to send to inside the dispersion piece 133 through oblique baffle 134, waste gas can flow to on adhesion net D1, divide into the polylith with adhesion net D1 etc. through many spacer bars D2, make adhesion net D1 can be fast effectively to the impurity in the waste gas carry out the adhesion processing, waste gas after handling can flow downwards to inside reaction membrane 135, sulfur dioxide in the waste gas can take place certain reaction with the active carbon in the reaction membrane 135, make active carbon can effectively carry out adsorption treatment to most sulfur dioxide in the waste gas, waste gas after preliminary absorption can be because inertia flows downwards on molecular sieve layer 132, molecular sieve layer 132 has higher adsorption, can effectively carry out high-efficient adsorption treatment with remaining sulfur dioxide in the waste gas, molecular sieve layer 132 is receiving that waste gas carries out atmospheric pressure and can retract downwards, support casing C4 through spring C2 with connecing knot C3 to mutually support, make casing C4 can effectively support molecular sieve layer 132, make molecular sieve layer 132 can keep the dispersed state, can effectively get rid of the sulfur dioxide in the waste gas, waste gas after getting rid of can flow down to purify intracavity 5 inside, carry out high efficiency processing to waste gas through purifying intracavity 5, waste gas after will handling is through discharging chamber 1 outwards discharge, improve the treatment effect of waste gas, guarantee the air circumstance on every side.

In summary, the invention adopts a combination of the discharge cavity, the fan, the inlet and the outlet, the removing device, the purification cavity and the machine body to form a new high-temperature waste gas purification device, the rubber arc block and the patch auxiliary fine filter screen are used for treating impurity dust in waste gas, the multilayer adsorption separation screen is used for efficiently treating the waste gas after primary treatment, dust and impurities in the waste gas are effectively treated, so that the dust is not easy to adhere to the inside of the device, and the sulfur dioxide in the waste gas can be effectively removed by efficiently adsorbing the sulfur dioxide in the waste gas through the cooperation of the reaction membrane and the molecular sieve layer, thereby improving the treatment effect of the waste gas.

While there have been shown and described what are at present considered the fundamental principles and essential features of the invention and its advantages, it will be apparent to those skilled in the art that the invention is not limited to the details of the foregoing exemplary embodiments, but is capable of other specific forms without departing from the spirit or essential characteristics thereof. The present embodiments are therefore to be considered in all respects as illustrative and not restrictive, the scope of the invention being indicated by the appended claims rather than by the foregoing description, and all changes which come within the meaning and range of equivalency of the claims are therefore intended to be embraced therein. Any reference sign in a claim should not be construed as limiting the claim concerned.

Furthermore, it should be understood that although the present description refers to embodiments, not every embodiment may contain only a single embodiment, and such description is for clarity only, and those skilled in the art should integrate the description, and the embodiments may be combined as appropriate to form other embodiments understood by those skilled in the art.

Claims

1. The utility model provides a high temperature exhaust gas purification equipment, its structure is including discharging chamber (1), fan (2), import and export (3), remove device (4), purifying chamber (5), organism (6), its characterized in that:

the machine body (6) is communicated with the discharge cavity (1) and the removing device (4), the removing device (4) and the discharge cavity (1) are provided with an inlet and an outlet (3), the machine body (6) is provided with a purification cavity (5), and the fan (2) is connected with the machine body (6) through an electric wire;

remove device (4) are including desulfurization subassembly (41), baffle (42), adsorption tank (43), interface (44), receiving chamber (45), body (46), establish on body (46) desulfurization subassembly (41), adsorption tank (43) and desulfurization subassembly (41), receiving chamber (45) switch on mutually, adsorption tank (43) both sides all are equipped with baffle (42), baffle (42) hug closely in body (46), be equipped with interface (44) on receiving chamber (45), interface (44) switch on with exit (3), desulfurization subassembly (41) are through organism (6) and purification chamber (5) intercommunication.

2. A high temperature exhaust gas purifying apparatus as set forth in claim 1, wherein: the desulfurization component (41) comprises a floating rod (411), a cavity (412), a treatment piece (413), a pulling strip (414), a clamping plate (415) and a guide plate (416), wherein the floating rod (411) penetrates through the guide plate (416) to be connected with the pulling strip (414), the pulling strip (414) is attached to the treatment piece (413), the guide plate (416) is connected with the clamping plate (415) and the treatment piece (413), the treatment piece (413) is installed on the cavity (412), the cavity (412) is connected with the clamping plate (415), the cavity (412) is arranged at the bottom of the body (46), the treatment piece (413) is communicated with the adsorption groove (43), and the guide plate (416) is communicated with the purification cavity (5) through a machine body (6).

3. A high temperature exhaust gas purifying apparatus as set forth in claim 2, wherein: the treatment part (413) comprises a circulation plate (131), a molecular sieve layer (132), a dispersion part (133), an inclined guide plate (134), a reaction membrane (135) and a top support part (136), the circulation plate (131) is arranged at the bottom of the molecular sieve layer (132), the top support part (136) is arranged inside the molecular sieve layer (132), the reaction membrane (135) is communicated with the molecular sieve layer (132) and the dispersion part (133), the dispersion part (133) is buckled with the inclined guide plate (134), the circulation plate (131) is jointed with a brace (414), the circulation plate (131) is communicated with a guide plate (416), the inclined guide plate (134) is arranged on a cavity (412), and the inclined guide plate (134) is communicated with an adsorption tank (43).

4. A high temperature exhaust gas purifying apparatus as set forth in claim 3, characterized in that: top support piece (136) are including splicing (C1), spring (C2), knot (C3), casing (C4), splicing (C1) both ends are all laminated at casing (C4) inner wall, splicing (C1) are connected with spring (C2), casing (C4) both ends are installed and are detained (C3), knot (C3) lock joint is inside molecular sieve layer (132).

5. A high temperature exhaust gas purifying apparatus as set forth in claim 3, characterized in that: the dispersion member (133) comprises an adhesion net (D1), a separation rod (D2) and a guide interface (D3), wherein the adhesion net (D1) is connected with the separation rod (D2), the adhesion net (D1) and the separation rod (D2) are annularly connected to the guide interface (D3), the adhesion net (D1) is communicated with the reaction membrane (135), and the guide interface (D3) is connected with the inclined guide plate (134).

6. A high temperature exhaust gas purifying apparatus as set forth in claim 1, wherein: adsorb groove (43) including water conservancy diversion chamber (431), adsorb and separate net (432), water conservancy diversion mouth (433), gliding arc board (434), auxiliary member (435), water conservancy diversion chamber (431) both sides all are equipped with gliding arc board (434), gliding arc board (434) link to each other with water conservancy diversion mouth (433), be equipped with on water conservancy diversion mouth (433) and adsorb and separate net (432), adsorb and separate net (432) lock joint on gliding arc board (434), it is equipped with auxiliary member (435) on net (432) to adsorb, auxiliary member (435) are installed on water conservancy diversion chamber (431), water conservancy diversion mouth (433) and oblique baffle (134) are put through mutually, gliding arc board (434) laminate mutually with baffle (42), water conservancy diversion chamber (431) and receiving chamber (45) are put through mutually.

7. A high temperature exhaust gas purifying apparatus as set forth in claim 6, wherein: the auxiliary part (435) is including gasbag (351), separate filter awl (352), fine filter screen (353), connect gas port (354), be equipped with two gas ports (354) on gasbag (351), gasbag (351) outer wall is connected with fine filter screen (353), install on fine filter screen (353) and separate filter awl (352), fine filter screen (353) are established on adsorbing and separating net (432), gasbag (351) are installed on water conservancy diversion chamber (431).

8. A high temperature exhaust gas purifying apparatus as set forth in claim 7, wherein: separate and strain awl (352) including rubber arc piece (E1), triangle thorn (E2), location axle (E3), paster (E4), open and shut piece (E5), stopper (E6), rubber arc piece (E1) symmetry laminating is stinging (E2) at the triangle, rubber arc piece (E1) link to each other with paster (E4), triangle thorn (E2) inside is equipped with and opens and shut piece (E5), open and shut piece (E5) are connected with stopper (E6) through location axle (E3), stopper (E6) bottom links to each other with triangle thorn (E2), triangle thorn (E2) are installed on fine filter screen (353).