阅读说明：本技术 防止杂质对导管堵塞的废气环保处理用高温气体降温装置 (High-temperature gas cooling device for waste gas environment-friendly treatment for preventing impurities from blocking guide pipe ) 是由 朱峰 于 2020-05-29 设计创作，主要内容包括：本发明提供防止杂质对导管堵塞的废气环保处理用高温气体降温装置,涉及废气处理领域,解决了储液桶内的液体多为静止状态的,不能够通过多元化的方式实现液体的流动,通过液体的流动进一步提高降温效果；不能够在促进液体流动的同时联动式先过滤网的清洁,初步过滤用的滤网清洁不够方便快捷的问题。防止杂质对导管堵塞的废气环保处理用高温气体降温装置,包括降温桶；所述降温桶内转动连接有两个混合结构。当伺服电机转动时拨动杆与伸缩气瓶接触并挤压伸缩气瓶,此时伸缩气瓶处于喷气状态,且伺服电机、拨动杆和压伸缩气瓶共同组成了气体混合式结构,从而当伺服电机转动实现搅拌混合的同时还能够实现气体混合。(The invention provides a high-temperature gas cooling device for waste gas environment-friendly treatment, which can prevent impurities from blocking a guide pipe, relates to the field of waste gas treatment, and solves the problems that most of liquid in a liquid storage barrel is in a static state, the liquid cannot flow in a diversified mode, and the cooling effect is further improved through the flow of the liquid; the cleaning of the linked first filter screen can not be realized while the liquid flow is promoted, and the problem that the cleaning of the filter screen for primary filtration is not convenient and fast enough is solved. The high-temperature gas cooling device for the waste gas environment-friendly treatment, which prevents impurities from blocking a guide pipe, comprises a cooling barrel; two mixing structures are rotationally connected in the cooling barrel. When the servo motor rotates, the poke rod is in contact with the telescopic gas cylinder and extrudes the telescopic gas cylinder, the telescopic gas cylinder is in a gas injection state at the moment, and the servo motor, the poke rod and the compressed and telescopic gas cylinder jointly form a gas mixing type structure, so that gas mixing can be realized when the servo motor rotates to realize stirring mixing.)

1. Prevent impurity from to pipe jam's waste gas environmental protection processing and use high-temperature gas heat sink, its characterized in that: comprises a cooling barrel (1); the cooling barrel (1) is rotatably connected with two mixing structures (2), the cooling barrel (1) is fixedly connected with a servo motor (3), and the cooling barrel (1) is fixedly connected with a telescopic gas cylinder (4); the servo motor (3) comprises a gear B (301) and a poke rod (302), the poke rod (302) and the gear B (301) are fixedly connected to a rotating shaft of the servo motor (3), and the gear B (301) is meshed with the gear A (203); the telescopic gas cylinder (4) comprises a gas inlet pipe (401), the gas inlet pipe (401) is connected to the telescopic gas cylinder (4), and the head end of the gas inlet pipe (401) is located in the cooling barrel (1); when the servo motor (3) rotates, the poke rod (302) is in contact with the telescopic gas cylinder (4) and extrudes the telescopic gas cylinder (4), the telescopic gas cylinder (4) is in a gas injection state, and the servo motor (3), the poke rod (302) and the compression telescopic gas cylinder (4) jointly form a gas mixing type structure; the cooling barrel (1) is connected with a connecting pipe (5), and the tail end of the connecting pipe (5) is connected with a filter box inserting pipe (6); a filter box (7) is inserted in the filter box insertion pipe (6), the filter box insertion pipe (6) is connected with a cleaning structure (8) in a sliding manner, and a shielding structure (9) is arranged in the filter box insertion pipe (6); referring to fig. 8, the shielding structure (9) includes two rectangular seats (901), two sliding rods (902), a stopper (903) and an elastic member (904), the two rectangular seats (901) are welded to the inner wall of the filter box insertion tube (6), and each rectangular seat (901) is welded with one sliding rod (902); the ends of the two sliding rods (902) are welded with a stop block (903), and the two sliding rods (902) are sleeved with elastic pieces (904); the stop block (903) is positioned above the cleaning hole (602), and the top end surface of the stop block (903) is of an inclined structure; when the cleaning brush (802) moves downwards, the toggle column (803) contacts the top end face of the inclined shape of the stop block (903) and pushes the stop block (903) to slide, and at the moment, the cleaning hole (602) is in an open state.

2. The apparatus for cooling high-temperature gas for environment-friendly treatment of exhaust gas for preventing clogging of guide pipes caused by impurities according to claim 1, wherein: the cooling barrel (1) comprises a heat dissipation groove (101), a heat dissipation pipe (102) and a cleaning brush (103), cooling liquid is filled in the cooling barrel (1), the heat dissipation pipe (102) is arranged in the cooling barrel (1), and the cleaning brush (103) is arranged at the head end of the heat dissipation pipe (102); the rear end face of the cooling barrel (1) is in a rectangular array shape and is provided with radiating grooves (101), and the radiating pipes (102) are in a semi-cylindrical groove-shaped structure.

3. The apparatus for cooling high-temperature gas for environment-friendly treatment of exhaust gas for preventing clogging of guide pipes caused by impurities according to claim 1, wherein: the mixing structure (2) comprises two rotating shafts (201), two stirring blades (202) and a gear A (203), the two rotating shafts (201) are rotatably connected to the cooling barrel (1), and two stirring blades (202) are symmetrically arranged on each rotating shaft (201); every all be connected with a gear A (203) on pivot (201), and two gear A (203) intermeshing to constitute synchronous revolution mechanic when meshing between two mixed structure (2).

4. The apparatus for cooling high-temperature gas for environment-friendly treatment of exhaust gas for preventing clogging of guide pipes caused by impurities according to claim 1, wherein: the mixing structure (2) further comprises a gauze seat (204), the gauze seat (204) is fixedly connected to the rotating shaft (201), and the rotating shaft (201) penetrates through the radiating pipe (102) and is in sealed rotary connection with the radiating pipe (102); a gauze seat (204) is fixedly connected to the rotating shaft (201), and a gauze is arranged on the gauze seat (204); the gauze is contacted with the cleaning brush (103), and when the rotating shaft (201) rotates, the cleaning brush (103) forms an automatic cleaning type structure of the gauze on the gauze seat (204).

5. The apparatus for cooling high-temperature gas for environment-friendly treatment of exhaust gas for preventing clogging of guide pipes caused by impurities according to claim 1, wherein: the filter cartridge insertion pipe (6) comprises clamping grooves (601) and cleaning holes (602), two clamping grooves (601) are symmetrically formed in the upper inner wall of the filter cartridge insertion pipe (6), and the bottom end face of the filter cartridge insertion pipe (6) is provided with the cleaning hole (602) in a rectangular structure; the filter box (7) comprises sliding seats A (701) and plugs (702), two sliding seats A (701) are symmetrically welded on the top end face of the filter box (7), and each sliding seat A (701) is elastically and slidably connected with one plug (702) through a sliding limiting rod and a spring; the plug (702) is matched with the clamping groove (601), the head end of the plug (702) is of an inclined structure, and when the filter box (7) is downwards slid and inserted into the filter box insertion pipe (6), the plug (702) and the clamping groove (601) are in an automatic clamping state.

6. The apparatus for cooling high-temperature gas for environment-friendly treatment of exhaust gas for preventing clogging of guide pipes caused by impurities according to claim 1, wherein: the filter box (7) further comprises handles (703), one handle (703) is welded on the top end face of each plug (702), the two handles (703) are in mirror image states, and the distance between the two handles (703) is 5 cm.

7. The apparatus for cooling high-temperature gas for environment-friendly treatment of exhaust gas for preventing clogging of guide pipes caused by impurities according to claim 1, wherein: the cleaning structure (8) comprises a sliding seat B (801), a cleaning brush (802) and a toggle column (803), the sliding seat B (801) is connected to the filter box insertion pipe (6) in a sliding mode, the bottom end face of the sliding seat B (801) is welded with the cleaning brush (802), and the center of the bottom end face of the cleaning brush (802) is welded with the toggle column (803); the brush head part of the cleaning brush (802) is contacted with the filter box (7), and the sliding seat B (801) and the cleaning brush (802) jointly form a manual sliding type cleaning structure of the filter box (7).

Technical Field

The invention belongs to the technical field of waste gas treatment, and particularly relates to a high-temperature gas cooling device for waste gas environment-friendly treatment, which is used for preventing impurities from blocking a guide pipe.

Background

The high-temperature waste gas refers to toxic and harmful gas discharged by human beings in the industrial production and living processes. In order to reduce the emission of pollutants, the waste gas needs to be treated, and the gas can be directly discharged to the atmosphere after reaching the standard.

As in application No.: the invention belongs to the technical field of waste gas treatment, and particularly relates to a high-temperature gas cooling device for waste gas environment-friendly treatment, which aims at the problem that the industrial waste gas needs to be cooled before being treated. According to the invention, the filter box, the activated carbon adsorption layer and the filter screen are arranged, so that the waste gas is preliminarily filtered before being cooled, the guide pipe can be effectively prevented from being blocked by impurities, and the practicability of the device can be effectively improved.

The high-temperature exhaust gas treatment device similar to the above application has the following disadvantages:

one is that the cooling efficiency is low, when the existing device uses liquid to cool, the liquid in the liquid storage barrel is mostly in a static state, the liquid flow can not be realized in a diversified manner, and the cooling effect is further improved through the liquid flow; moreover, the pipe is easily blockked up the fault rate by impurity higher in the use of current device, and on the one hand can not promote the cleanness of the first filter screen of coordinated type when liquid flows, and on the other hand, the filter screen of prefiltration usefulness is clean convenient and fast inadequately.

Accordingly, the present invention is to provide a high-temperature gas cooler for environmental protection treatment of exhaust gas, which can prevent impurities from blocking a conduit, by improving the existing structure and defects, so as to achieve the purpose of higher practical value.

Disclosure of Invention

In order to solve the technical problems, the invention provides a high-temperature gas cooling device for waste gas environment-friendly treatment, which can prevent impurities from blocking a guide pipe, and aims to solve the problems that the cooling efficiency is low in the prior art, when the prior device is used for cooling by using liquid, the liquid in a liquid storage barrel is mostly in a static state, the liquid cannot flow in a diversified manner, and the cooling effect is further improved by the flow of the liquid; moreover, the pipe is easily blockked up the fault rate by impurity higher in the use of current device, and on the one hand can not promote the cleanness of the first filter screen of coordinated type when liquid flows, and on the other hand, the filter screen of prefiltration usefulness is clean convenient and fast's problem inadequately.

The invention aims and effects of a high-temperature gas cooling device for waste gas environment-friendly treatment, which prevents impurities from blocking a guide pipe, and is achieved by the following specific technical means:

the high-temperature gas cooling device for the waste gas environment-friendly treatment, which prevents impurities from blocking a guide pipe, comprises a cooling barrel; the cooling barrel is connected with two mixing structures in a rotating manner, a servo motor is fixedly connected onto the cooling barrel, and a telescopic gas cylinder is fixedly connected onto the cooling barrel; the servo motor comprises a gear B and a poke rod, the poke rod and the gear B are fixedly connected to a rotating shaft of the servo motor, and the gear B is meshed with the gear A; the telescopic gas cylinder comprises a gas inlet pipe, the telescopic gas cylinder is connected with the gas inlet pipe, and the head end of the gas inlet pipe is positioned in the cooling barrel; when the servo motor rotates, the poke rod is in contact with the telescopic gas cylinder and extrudes the telescopic gas cylinder, the telescopic gas cylinder is in a gas injection state at the moment, and the servo motor, the poke rod and the compressed and telescopic gas cylinder jointly form a gas mixing type structure, so that gas mixing can be realized while stirring and mixing are realized when the servo motor rotates; the cooling barrel is connected with a connecting pipe, and the tail end of the connecting pipe is connected with the filter box inserting pipe; the filter cartridge is inserted into the filter cartridge insertion pipe, the filter cartridge insertion pipe is connected with a cleaning structure in a sliding mode, and a shielding structure is arranged in the filter cartridge insertion pipe; the shielding structure comprises two rectangular seats, two sliding rods, a stop block and an elastic piece, the two rectangular seats are welded on the inner wall of the filter box inserting pipe, and each rectangular seat is welded with one sliding rod; the ends of the two sliding rods are welded with the stop blocks, and the two sliding rods are sleeved with the elastic pieces; the stop block is positioned above the cleaning hole, and the top end surface of the stop block is of an inclined structure; when the cleaning brush moves downwards, the stirring column is in contact with the inclined top end surface of the stop block and pushes the stop block to slide, the cleaning hole is in an opening state at the moment, therefore, the cleaning structure can be used for cleaning while opening and closing the cleaning hole, and the inclined stop block at the top end surface can play a role in collecting residues.

Further, the cooling barrel comprises a heat dissipation groove, a heat dissipation pipe and a cleaning brush, cooling liquid is filled in the cooling barrel, the heat dissipation pipe is arranged in the cooling barrel, and the cleaning brush is arranged at the head end of the heat dissipation pipe; the cooling barrel rear end face is rectangular array and has been seted up the radiating groove, and the radiating tube is semi-cylindrical groove-shaped structure.

Furthermore, the mixing structure comprises two rotating shafts, two stirring blades and a gear A, wherein the two rotating shafts are rotatably connected to the cooling barrel, and two stirring blades are symmetrically arranged on each rotating shaft; every equal fixedly connected with gear A in the pivot, and two gear A intermeshing to constitute synchronous revolution mechanic when meshing between two mixed structure.

Furthermore, the mixing structure also comprises a gauze seat which is fixedly connected to the rotating shaft, and the rotating shaft penetrates through the radiating pipes and is in sealed rotary connection with the radiating pipes; the rotating shaft is fixedly connected with a gauze seat, and a gauze is arranged on the gauze seat; the gauze is contacted with the cleaning brush, and when the rotating shaft rotates, the cleaning brush forms an automatic cleaning structure of the gauze on the gauze seat.

Furthermore, the filter cartridge insertion pipe comprises clamping grooves and cleaning holes, two clamping grooves are symmetrically formed in the inner wall of the filter cartridge insertion pipe, and the bottom end face of the filter cartridge insertion pipe is provided with a cleaning hole of a rectangular structure; the filter box comprises sliding seats A and a plug, two sliding seats A are symmetrically welded on the top end face of the filter box, and each sliding seat A is elastically and slidably connected with one plug through a sliding limiting rod and a spring; the plug is matched with the clamping groove, the head end of the plug is of an inclined structure, and the plug and the clamping groove are in an automatic clamping state when the filter box is downwards slid and inserted into the filter box inserting pipe.

Further, the filter cartridge still includes the handle, and every plug top end face all welds has a handle, and two handles are the mirror image state, and the interval between two handles is 5 cm.

Furthermore, the cleaning structure comprises a sliding seat B, a cleaning brush and a shifting column, wherein the sliding seat B is connected to the filter box insertion pipe in a sliding mode, the bottom end face of the sliding seat B is welded with the cleaning brush, and the shifting column is welded in the center of the bottom end face of the cleaning brush; the brush head part of the cleaning brush is contacted with the filter box, and the sliding seat B and the cleaning brush jointly form a manual sliding type cleaning structure of the filter box.

Compared with the prior art, the invention has the following beneficial effects:

the device has high cooling efficiency, on one hand, the mixing structure can be driven to mix liquid in the cooling barrel through the rotation of the servo motor on the other hand through the matching arrangement of the mixing structure and the servo motor, so that the flowing of the liquid can be enhanced, the heat dissipation efficiency is improved, and in addition, one gear A is fixedly connected to each rotating shaft, the two gears A are mutually meshed, and a synchronous rotating structure is formed between the two mixing structures when the two mixing structures are meshed, so that the mixing efficiency can be improved; secondly, when the servo motor rotates, the poke rod is in contact with the telescopic gas cylinder and extrudes the telescopic gas cylinder, the telescopic gas cylinder is in a gas injection state at the moment, and the servo motor, the poke rod and the compressed and stretched gas cylinder jointly form a gas mixing type structure, so that gas mixing can be realized while stirring and mixing are realized when the servo motor rotates; on the other hand, the rear end face of the cooling barrel is provided with the radiating grooves in a rectangular array shape, and the radiating pipes are in a semi-cylindrical groove-shaped structure, so that the radiating capacity of the cooling barrel can be improved.

This device can adopt the jam probability that multiple clear mode reduces the pipe, and can realize the switching of row's cinder notch simultaneously when clearing up the residue, specifically as follows: firstly, a gauze seat is fixedly connected to the rotating shaft, and a gauze is arranged on the gauze seat; the gauze is contacted with the cleaning brush, and when the rotating shaft rotates, the cleaning brush forms an automatic cleaning structure of the gauze on the gauze seat; secondly, the head part of the cleaning brush is contacted with the filter box, the sliding seat B and the cleaning brush jointly form a manual sliding type cleaning structure of the filter box, the stop block is positioned above the cleaning hole, and the top end surface of the stop block is of an inclined structure; when the cleaning brush moves downwards, the stirring column is in contact with the inclined top end surface of the stop block and pushes the stop block to slide, the cleaning hole is in an opening state at the moment, therefore, the cleaning structure can be used for cleaning while opening and closing the cleaning hole, and the inclined stop block at the top end surface can play a role in collecting residues.

Drawings

Fig. 1 is a schematic axial view of the present invention.

FIG. 2 is a schematic view of the cooling barrel removed from the axial view of the present invention.

Fig. 3 is an enlarged schematic view of fig. 2 at a.

Fig. 4 is an enlarged schematic view of fig. 2B according to the present invention.

FIG. 5 is an enlarged schematic view of the cooling portion of the present invention.

Fig. 6 is an enlarged view of the structure of fig. 5C according to the present invention.

FIG. 7 is an enlarged, axial view of the connecting tube, filter cartridge, cleaning structure and shielding structure of the present invention.

Fig. 8 is a schematic axial view of the filter cassette of fig. 7 with the filter cassette removed in accordance with the present invention.

Fig. 9 is an enlarged view of fig. 8D according to the present invention.

In the drawings, the corresponding relationship between the component names and the reference numbers is as follows:

1. a cooling barrel; 101. a heat sink; 102. a radiating pipe; 103. a cleaning brush; 2. a hybrid structure; 201. a rotating shaft; 202. a stirring blade; 203. a gear A; 204. a screen holder; 3. a servo motor; 301. a gear B; 302. a poke rod; 4. a telescopic gas cylinder; 401. an air inlet pipe; 5. a connecting pipe; 6. a filter cartridge insertion pipe; 601. a card slot; 602. cleaning the hole; 7. a filter cartridge; 701. a sliding seat A; 702. a plug; 703. a handle; 8. cleaning the structure; 801. a sliding seat B; 802. cleaning with a brush; 803. shifting the column; 9. a shielding structure; 901. a rectangular base; 902. a slide bar; 903. a stopper; 904. an elastic member.

Detailed Description

The embodiments of the present invention will be described in further detail with reference to the drawings and examples. The following examples are intended to illustrate the invention but are not intended to limit the scope of the invention.

In the description of the present invention, "a plurality" means two or more unless otherwise specified; the terms "upper", "lower", "left", "right", "inner", "outer", "front", "rear", "head", "tail", and the like, indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings, are only for convenience in describing and simplifying the description, and do not indicate or imply that the device or element referred to must have a particular orientation, be constructed in a particular orientation, and be operated, and thus, should not be construed as limiting the invention. Furthermore, the terms "first," "second," "third," and the like are used for descriptive purposes only and are not to be construed as indicating or implying relative importance.

In the description of the present invention, it is to be noted that, unless otherwise explicitly specified or limited, the terms "connected" and "connected" are to be interpreted broadly, e.g., as being fixed or detachable or integrally connected; can be mechanically or electrically connected; may be directly connected or indirectly connected through an intermediate. The specific meanings of the above terms in the present invention can be understood in specific cases to those skilled in the art.