CN220539808U - Waste heat recycling equipment of air compressor - Google Patents

Abstract

The utility model relates to the technical field of air compressors, in particular to an air compressor waste heat recycling device. The heat exchange device comprises a heat exchange frame, wherein a plurality of heat exchange plates are arranged in the heat exchange frame, and connecting rods which are fixedly connected are arranged on the side walls of the two ends of the heat exchange frame; the adjusting device is arranged at the bottom end of the heat exchange frame and comprises a sliding frame, the surface of the sliding frame is in butt joint with the bottom surface of the heat exchange frame, a positioning groove is formed in the position, corresponding to the heat exchange frame, of the surface of the sliding frame, the inner wall of the positioning groove is clamped with the bottom end of the heat exchange frame, the inner wall of the sliding frame is slidably connected with a bottom plate, one side of the sliding frame is fixedly connected with a rack, and one end of the bottom plate is fixedly connected with a servo motor. The air compressor waste heat recycling device provided by the utility model has the advantages that the whole plate heat exchanger can be conveniently adjusted and moved in position, so that the plate heat exchanger and a pipeline can be quickly connected.

Description

Waste heat recycling equipment of air compressor

Technical Field

The utility model relates to the technical field of air compressors, in particular to an air compressor waste heat recycling device.

Background

Air compressors are operated using reciprocating pistons, rotating blades or rotating screws, and are a device for compressing gas, which is common in everyday life.

Prior art is such as the utility model of publication No. CN219223437U, and this patent discloses a plate heat exchanger, and this patent includes the stripper plate, the quantity of stripper plate is two, two fixedly connected with piece slab between the stripper plate, recess a has been seted up to the upper end surface of slab, and recess B has been seted up to its lower extreme surface, the downside fixedly connected with dead lever of stripper plate, the surface and the recess B of dead lever, the upside fixedly connected with fixed block of stripper plate, the internal surface elastic connection of fixed block has a plurality of elastic plates, the downside and the recess a of elastic plate are mutually laminated. According to the utility model, the elastic plates are elastically connected with the fixed blocks, so that the elastic plates can be contracted by disassembling the fixed plates, and the elastic plates are separated from the grooves A, so that the damaged plate can be disassembled and assembled conveniently, the disassembly difficulty is reduced, and the disassembly and repair efficiency is improved.

The inventor finds that the plate heat exchanger is an important component part of the air compressor waste heat recovery device in daily life, and generally needs to be used for cold and heat recovery, and because the whole plate heat exchanger is longer in pipeline and heavier in whole when being in butt joint with the pipeline, the situation that the butt joint position is deviated easily occurs, so that the problem that the whole plate heat exchanger is inconvenient to quickly butt joint with the pipeline is caused.

Therefore, it is necessary to provide a new apparatus for recycling waste heat of an air compressor to solve the above technical problems.

Disclosure of Invention

In order to solve the technical problems, the utility model provides the air compressor waste heat recycling equipment.

The utility model provides air compressor waste heat recycling equipment, which comprises: the heat exchange rack is internally provided with a plurality of heat exchange plates, and the side walls of the two ends of the heat exchange rack are respectively provided with a connecting rod which is fixedly connected; the adjusting device is arranged at the bottom end of the heat exchange frame and comprises a sliding frame, the surface of the sliding frame is abutted against the bottom surface of the heat exchange frame, a positioning groove is formed in the position, corresponding to the heat exchange frame, of the surface of the sliding frame, the inner wall of the positioning groove is clamped with the bottom end of the heat exchange frame, the inner wall of the sliding frame is connected with a bottom plate in a sliding manner, one side of the sliding frame is fixedly connected with a rack, one end of the bottom plate is fixedly connected with a servo motor, the output end of the servo motor is fixedly connected with a gear, and the tooth surface of the gear is meshed with the tooth surface of the rack; and the auxiliary device is arranged on the upper end surface of the heat exchange frame.

The effects achieved by the components are as follows: when carrying out long-time operation and use to air compressor machine waste heat recovery and utilizing equipment, need utilize plate heat exchanger to carry out cold and hot recovery, because the skew condition of position appears easily in whole plate heat transfer device wherein when docking with the pipeline, in order to conveniently carry out convenient regulation to the position of whole plate heat exchanger this moment, through the removal to the sliding frame position of heat exchange frame bottom, utilize servo motor on the bottom plate to drive the rotation between gear and the rack to let the rack drive the removal of sliding frame position, thereby it is spacing to the quick travel of heat exchange frame position on the sliding frame effectively.

Preferably, one side of the bottom plate away from the rack is fixedly connected with a limiting rod, the arc surface of the limiting rod is slidably connected with a limiting block, and one end of the limiting block is fixedly connected with the side wall of the sliding frame.

The effects achieved by the components are as follows: when the position of the sliding frame is slid, the limiting rod on the bottom plate and the limiting block on the sliding frame are utilized to slide mutually, so that the sliding frame is prevented from falling off due to the position deviation.

Preferably, the arc surface thread of the limiting block penetrates through a screw rod, and one end of the screw rod is abutted against the arc surface of the limiting rod.

The effects achieved by the components are as follows: after the whole sliding frame is moved to the appointed position, the whole sliding frame and the heat exchange frame are fixed and limited for convenience, and at the moment, the screw rod on the limiting block is used for extrusion and fixation.

Preferably, the bottom surface of bottom plate fixedly connected with backup pad, a plurality of anti-skidding line has been seted up to the surface of backup pad.

The effects achieved by the components are as follows: when supporting spacingly to whole heat exchange frame, utilize the backup pad on the bottom plate to support the protection, and for the convenience to protect the bottom plate, reuse the backup pad to carry out effectual support spacingly this moment.

Preferably, the auxiliary device comprises a fixing frame, both ends of the fixing frame are fixedly connected with the upper end surface of the heat exchange frame, a plurality of driving rods penetrate through the surface of the fixing frame in a sliding mode, a plurality of driving rods penetrate through the inner walls of the driving rods in a sliding mode, an extrusion frame is fixedly connected with one end of each moving rod, which is close to a heat exchange plate, of each moving rod, the inner walls of the extrusion frames are abutted to the upper end of each heat exchange plate, a rotating shaft is connected with the arc surface of the upper end of each driving rod in a threaded mode, the bottom surface of each rotating shaft is abutted to the surface of the fixing frame, springs are sleeved on the arc surface of each moving rod, and both ends of each spring are fixedly connected with the extrusion frame and the driving rods respectively.

The effects achieved by the components are as follows: after the heat exchange plates on the heat exchange frame are used for a long time, the heat exchange plates need to be cleaned, at this time, in order to fix and limit the positions of all the heat exchange plates, a fixing frame on the heat exchange frame is utilized, a driving rod on the fixing frame is extruded and fixed with a rotating shaft, a moving rod sliding on the driving rod is utilized to drive an extrusion frame to extrude and limit the heat exchange plates, and the tensile force generated by a spring on the moving rod can effectively extrude and fix the extrusion frame, so that the position adjustment of the heat exchange plates on the heat exchange frame is facilitated.

Preferably, the arc surface of the rotating shaft is fixedly connected with a plurality of protruding blocks, and the protruding blocks are uniformly distributed on the arc surface of the rotating shaft.

The effects achieved by the components are as follows: when the rotating shaft is rotated, friction can be effectively increased by utilizing the convex blocks on the rotating shaft, so that the rotating shaft can be used conveniently and better.

Preferably, the bottom of the rotating shaft is rotationally connected with a gasket, and the gasket is a rubber gasket.

The effects achieved by the components are as follows: when the positions of the rotating shaft and the fixing frame are extruded and limited, the gasket on the rotating shaft can be used for effectively protecting the rotating shaft.

Compared with the related art, the air compressor waste heat recycling equipment provided by the utility model has the following advantages that

The beneficial effects are that:

the utility model provides air compressor waste heat recovery and utilization equipment, when the air compressor waste heat recovery and utilization equipment is operated for a long time, cold and heat recovery is needed to be carried out by utilizing a plate heat exchanger, because the position deviation condition easily occurs when the whole plate heat exchange device is in butt joint with a pipeline, the position of the whole plate heat exchanger is conveniently adjusted through the operation of an adjusting device, and a servo motor on a bottom plate is utilized to drive a gear and a rack to rotate through the movement of the sliding frame at the bottom end of a heat exchange frame, so that the rack drives the sliding frame to move, and the rapid movement of the position of the heat exchange frame on the sliding frame is effectively limited.

After the heat exchange plates on the heat exchange frame are used for a long time, the heat exchange plates need to be cleaned, the fixing limit of the positions of all the heat exchange plates is achieved through the operation of the auxiliary device, at this time, the fixing frame on the heat exchange frame is utilized, the driving rod on the fixing frame is fixedly extruded with the rotating shaft, the sliding moving rod on the driving rod drives the extrusion frame to extrude and limit the heat exchange plates, and the tensile force generated by the springs on the moving rod can effectively extrude and fix the extrusion frame, so that the position adjustment of the heat exchange plates on the heat exchange frame is facilitated.

Drawings

FIG. 1 is a schematic perspective view of the present utility model;

FIG. 2 is a schematic view of the adjusting device shown in FIG. 1;

FIG. 3 is a schematic view of a part of the adjusting device shown in FIG. 1;

fig. 4 is a schematic structural view of the auxiliary device shown in fig. 1.

Reference numerals in the drawings: 1. a heat exchange frame; 2. a connecting rod; 3. a heat exchange plate; 4. an adjusting device; 401. a bottom plate; 402. a sliding frame; 403. a servo motor; 404. a gear; 405. a rack; 406. a positioning groove; 407. a support plate; 408. a limit rod; 409. a limiting block; 410. a screw; 5. an auxiliary device; 51. a fixing frame; 52. a bump; 53. a driving rod; 54. a rotating shaft; 55. a moving rod; 56. extruding a frame; 57. a spring; 58. a gasket.

Detailed Description

The present utility model will be described in further detail with reference to the drawings and examples, in order to make the objects, technical solutions and advantages of the present utility model more apparent. It should be understood that the specific embodiments described herein are for purposes of illustration only and are not intended to limit the scope of the utility model.

Specific implementations of the utility model are described in detail below in connection with specific embodiments.

Referring to fig. 1 to 4, an air compressor waste heat recycling device provided in an embodiment of the present utility model includes: the heat exchange frame 1, a plurality of heat exchange plates 3 are arranged in the heat exchange frame 1, and connecting rods 2 which are fixedly connected are arranged on the side walls of the two ends of the heat exchange frame 1; the adjusting device 4, adjusting device 4 installs in the bottom of heat exchange frame 1, auxiliary device 5, and auxiliary device 5 installs at the upper end surface of heat exchange frame 1.

In the embodiment of the utility model, referring to fig. 2 and 3, the adjusting device 4 includes a sliding frame 402, the surface of the sliding frame 402 is abutted against the bottom surface of the heat exchange frame 1, a positioning groove 406 is formed on the surface of the sliding frame 402 corresponding to the position of the heat exchange frame 1, the inner wall of the positioning groove 406 is clamped against the bottom end of the heat exchange frame 1, the inner wall of the sliding frame 402 is slidably connected with a bottom plate 401, one side of the sliding frame 402 is fixedly connected with a rack 405, one end of the bottom plate 401 is fixedly connected with a servo motor 403, the output end of the servo motor 403 is fixedly connected with a gear 404, the tooth surface of the gear 404 is meshed with the tooth surface of the rack 405, one side of the bottom plate 401 far away from the rack 405 is fixedly connected with a limiting rod 408, the arc surface of the limiting rod 408 is slidably connected with a limiting block 409, one end of the limiting block 409 is fixedly connected with a screw 410 through which is threaded, one end of the screw 410 is abutted against the arc surface of the limiting rod 408, the bottom end surface of the bottom plate 401 is fixedly connected with a supporting plate 407, and the surface of the supporting plate 407 is provided with a plurality of anti-skid threads;

in the embodiment of the present utility model, referring to fig. 4, the auxiliary device 5 includes a fixing frame 51, two ends of the fixing frame 51 are fixedly connected with an upper end surface of the heat exchange frame 1, a plurality of driving rods 53 are slidably penetrated through a surface of the fixing frame 51, inner walls of the plurality of driving rods 53 are slidably penetrated through a moving rod 55, one end of the moving rod 55 close to the heat exchange plate 3 is fixedly connected with an extrusion frame 56, the inner wall of the extrusion frame 56 is abutted against an upper end of the heat exchange plate 3, an upper end arc surface of the driving rod 53 is in threaded connection with a rotating shaft 54, a bottom surface of the rotating shaft 54 is abutted against a surface of the fixing frame 51, an arc surface of the moving rod 55 is sleeved with a spring 57, two ends of the spring 57 are fixedly connected with the extrusion frame 56 and the driving rod 53 respectively, a plurality of bumps 52 are uniformly distributed on an arc surface of the rotating shaft 54, a gasket 58 is rotatably connected with a bottom end of the rotating shaft 54, and the gasket 58 is a rubber gasket 58;

the working principle of the air compressor waste heat recycling device provided by the utility model is as follows: when the air compressor waste heat recycling device is used for a long time, the plate heat exchanger is required to be utilized for cold and heat recovery, and because the whole plate heat exchange device is easy to generate position deviation when being in butt joint with a pipeline, in order to conveniently adjust the position of the whole plate heat exchanger, the position of the sliding frame 402 is conveniently prevented from being deviated and fallen by utilizing the position of the sliding frame 402 by moving the sliding frame 402 and utilizing the servo motor 403 on the bottom plate 401 to drive the rotation between the gear 404 and the rack 405, so that the rack 405 drives the sliding frame 402 to move, thereby effectively limiting the quick movement of the position of the heat exchange frame 1 on the sliding frame 402, and when the position of the sliding frame 402 is slid, the limiting rod 408 on the bottom plate 401 and the limiting block 409 on the sliding frame 402 are utilized, after moving whole sliding frame 402 to appointed position, in order to conveniently fix spacing whole sliding frame 402 and heat exchange frame 1, utilize screw rod 410 on stopper 409 to extrude fixedly this moment, when supporting spacing whole heat exchange frame 1, utilize backup pad 407 on bottom plate 401 to support the protection, and in order to conveniently protect bottom plate 401, reuse backup pad 407 to carry out effectual support spacing this moment, through the operation to adjusting device 4, the position to whole plate heat exchanger has been reached, through the removal to the sliding frame 402 position of heat exchange frame 1 bottom, utilize servo motor 403 on bottom plate 401 to drive the rotation between gear 404 and the rack 405, thereby let rack 405 drive the removal of sliding frame 402 position, thereby effectively the quick travel of heat exchange frame 1 position on the sliding frame 402 is spacing.

After the heat exchange plates 3 on the heat exchange frame 1 are used for a long time, the heat exchange plates 3 need to be cleaned, at this time, in order to fix and limit the positions of all the heat exchange plates 3, at this time, the fixing frame 51 on the heat exchange frame 1 is utilized, the driving rod 53 on the fixing frame 51 and the rotating shaft 54 are extruded and fixed, the sliding moving rod 55 on the driving rod 53 is utilized to drive the extrusion frame 56 to extrude and limit the positions of the heat exchange plates 3, the pulling force generated by the springs 57 on the moving rod 55 can effectively extrude and fix the extrusion frame 56, thereby being beneficial to position adjustment of the heat exchange plates 3 on the heat exchange frame 1, when the rotating shaft 54 rotates, the protruding blocks 52 on the rotating shaft 54 can effectively increase friction, thereby being convenient for better use the rotating shaft 54, when the positions of the rotating shaft 54 and the fixing frame 51 are extruded and limited, the gasket 58 on the rotating shaft 54 can effectively protect and use the rotating shaft 54, at this time, the fixing frame 56 is extruded and fixed by the operation of the auxiliary device 5, the pulling force generated by the springs 57 on the moving rod 55 can effectively extrude and fix the positions of the heat exchange plates 3 on the fixing frame 55, thereby effectively extruding the fixing frame 55 by utilizing the driving rod 53 on the rotating shaft 53 to extrude and the fixing frame 55.

The circuits and control involved in the present utility model are all of the prior art, and are not described in detail herein.

The foregoing description is only illustrative of the present utility model and is not intended to limit the scope of the utility model, and all equivalent structures or equivalent processes or direct or indirect application in other related technical fields are included in the scope of the present utility model.

Claims (7)

1. Waste heat recovery and utilization equipment of an air compressor, which is characterized by comprising:

the heat exchange device comprises a heat exchange frame (1), wherein a plurality of heat exchange plates (3) are arranged in the heat exchange frame (1), and connecting rods (2) which are fixedly connected are arranged on the side walls of the two ends of the heat exchange frame (1);

the adjusting device (4), the bottom at heat exchange frame (1) is installed to adjusting device (4), adjusting device (4) include slip frame (402), the surface of slip frame (402) and the bottom surface looks butt of heat exchange frame (1), constant head tank (406) have been seted up to the position that corresponds heat exchange frame (1) on slip frame (402) surface, the inner wall of constant head tank (406) and heat exchange frame (1) bottom looks joint, the inner wall sliding connection of slip frame (402) has bottom plate (401), one side fixedly connected with rack (405) of slip frame (402), one end fixedly connected with servo motor (403) of bottom plate (401), the output fixedly connected with gear (404) of servo motor, the tooth face of gear (404) meshes with the tooth face of rack (405);

and the auxiliary device (5) is arranged on the upper end surface of the heat exchange frame (1).

2. The air compressor waste heat recovery and utilization device according to claim 1, wherein a limiting rod (408) is fixedly connected to one side, far away from the rack (405), of the bottom plate (401), a limiting block (409) is slidably connected to an arc surface of the limiting rod (408), and one end of the limiting block (409) is fixedly connected with the side wall of the sliding frame (402).

3. The air compressor waste heat recovery and utilization device according to claim 2, wherein the arc surface threads of the limiting block (409) penetrate through a screw (410), and one end of the screw (410) is abutted against the arc surface of the limiting rod (408).

4. The air compressor waste heat recovery and utilization device according to claim 1, wherein a supporting plate (407) is fixedly connected to the bottom end surface of the bottom plate (401), and a plurality of anti-skid patterns are formed on the surface of the supporting plate (407).

5. The air compressor waste heat recovery and utilization device according to claim 1, wherein the auxiliary device (5) comprises a fixing frame (51), two ends of the fixing frame (51) are fixedly connected with the surface of the upper end of the heat exchange frame (1), a plurality of driving rods (53) are slidably penetrated through the surface of the fixing frame (51), a plurality of moving rods (55) are slidably penetrated through the inner walls of the driving rods (53), one end, close to the heat exchange plate (3), of each moving rod (55) is fixedly connected with an extrusion frame (56), the inner walls of the extrusion frames (56) are abutted against the upper end of the heat exchange plate (3), a rotating shaft (54) is in threaded connection with the arc surface of the upper end of each driving rod (53), the bottom surface of each rotating shaft (54) is abutted against the surface of the fixing frame (51), springs (57) are sleeved on the arc surfaces of the moving rods (55), and two ends of each spring (57) are fixedly connected with the extrusion frames (56) and the driving rods (53).

6. The air compressor waste heat recovery and utilization device according to claim 5, wherein the arc surface of the rotating shaft (54) is fixedly connected with a plurality of protruding blocks (52), and the protruding blocks (52) are uniformly distributed on the arc surface of the rotating shaft (54).

7. The air compressor waste heat recovery and utilization device according to claim 5, wherein a gasket (58) is rotatably connected to the bottom end of the rotating shaft (54), and the gasket (58) is a rubber gasket (58).