CN115307341B

CN115307341B - Improved generation air source heat pump

Info

Publication number: CN115307341B
Application number: CN202210952468.5A
Authority: CN
Inventors: 田海燕; 陶宏亮
Original assignee: 1890 Safety Technology Jiangsu Co ltd
Current assignee: 1890 Safety Technology Jiangsu Co ltd
Priority date: 2022-08-09
Filing date: 2022-08-09
Publication date: 2023-11-14
Anticipated expiration: 2042-08-09
Also published as: CN115307341A

Abstract

The utility model relates to the technical field of air energy heat pumps, in particular to an improved air energy heat pump, which comprises an air energy heat pump body, a supporting unit and a filtering unit, wherein the supporting unit is arranged on the air energy heat pump body; the existing air energy heat pump has the following problems: the shell of the air energy heat pump is not damped and buffered and is easy to deform and damage; the air cannot be filtered, so dust and granular impurities in the air are easy to drill into the air energy heat pump, and the normal operation of the air energy heat pump is easy to be influenced; the utility model can buffer the air energy heat pump body to reduce the vibration amplitude in the working process of the air energy heat pump body, thereby preventing the air energy heat pump body from being damaged due to vibration; according to the air-source heat pump, the air-permeable net frame can be protected through the net hole cover, sundries in air are prevented from penetrating through the air-permeable net frame and drilling into the air-source heat pump body, the net hole cover can be cleaned, and the influence on air permeability caused by the fact that sundries are attached to the outer wall of the net hole cover is avoided.

Description

Improved generation air source heat pump

Technical Field

The utility model relates to the technical field of air-source heat pumps, in particular to an improved air-source heat pump.

Background

The air energy heat pump utilizes the heat in the air to generate heat energy, can provide different hot water and cooling and heating requirements with high water pressure and constant temperature all day, consumes less energy, and has the advantages of convenient installation, safe use, energy saving, electricity saving and the like.

Air-source heat pumps are also provided in the prior art, for example: the novel air-source heat pump disclosed in the Chinese patent with publication number of CN209415838U can vibrate up and down when a compressor vibrates, the sleeve and the guide post can slide relatively, and the first spring and the second spring are compressed or stretched, so that the fixing plate can be well buffered, vibration can be eliminated, and vibration between the carrier plate and the support plate and noise of the compressor can be further reduced through the asphalt damping plate.

However, the above patent has the following problems: 1. above-mentioned patent only carries out shock attenuation to the compressor and the air energy heat pump shakes in the course of the work itself easily, so the shell of air energy heat pump can not receive shock attenuation and buffering and take place deformation and damage easily, in addition, first spring and second spring that this patent provided can't adjust, and then can't support the compressor of equidimension difference.

2. Because there are debris such as dust, particulate matter in the air, and the above-mentioned patent can't filter the air, therefore the air energy heat pump is in the course of the work, and dust and the particulate debris in the air bore into the air energy heat pump inside easily to the debris in the air influences the normal work of air energy heat pump easily.

Disclosure of Invention

1. The technical problems to be solved are as follows: the improved air source heat pump provided by the utility model can solve the problems pointed out in the background technology.

2. The technical scheme is as follows: in order to achieve the above purpose, the utility model adopts the following technical scheme that the improved air energy heat pump comprises an air energy heat pump body, a supporting unit and a filtering unit, wherein a plurality of through holes are formed in the lower end of the air energy heat pump body in a penetrating manner, and ventilation net frames are symmetrically arranged on the front and back of the outer wall of the air energy heat pump body.

The supporting unit comprises a base, a guide chute, a damping piece, an execution plate and a jacking plate, wherein: the air-source heat pump comprises an air-source heat pump body, and is characterized in that a base is arranged below the air-source heat pump body, a plurality of supporting groups are arranged at the upper end of the base from left to right at equal intervals, each supporting group comprises two guide sliding grooves which are symmetrically distributed around the base, shock absorbing pieces are arranged in each guide sliding groove, an execution plate is arranged at the upper end of the shock absorbing piece of the same supporting group, two jacking plates are symmetrically arranged around the upper end of the execution plate, and the upper ends of the jacking plates are connected with the lower end of the air-source heat pump body.

The filter unit includes the guipure, holds board, sliding tray, linkage board, U-shaped board, revolving drum and clean subassembly, wherein: the outer wall of air energy heat pump body is provided with two mesh hole covers through detachable mode front and back symmetry, be the mode of matrix arrangement on the mesh hole cover and run through and set up a plurality of bell mouths, the diameter of bell mouths reduces gradually from the mesh hole cover to the one side that is close to this middle part of air energy heat pump, and the mesh cover is established in the outside of ventilative frame, both sides wall all about the mesh cover about the air energy heat pump body install two and accept the board, run through on the board and set up the sliding tray, sliding butt joint has the linkage board in the sliding tray, U-shaped board is installed jointly to the one side that the two linkage boards of air energy heat pump body with one side kept away from the mesh hole cover, and the opposite side rotation of two linkage boards of air energy heat pump body with one side is provided with rotatory section of thick bamboo, rotatory section of thick bamboo internally mounted has clean subassembly.

Preferably, the damping piece includes sliding block, two-way screw rod, backup pad, connecting plate, spacing spout and support spring rod, wherein: the sliding block is arranged in the guide sliding groove in a sliding way, a plurality of bidirectional screws corresponding to the positions of the supporting groups are arranged on the base in a rotating way from left to right at equal intervals, the bidirectional screws are connected through belt transmission, the bidirectional screws penetrate through the sliding block in a threaded fit mode, the supporting plate is arranged at the upper end of the sliding block, limit sliding grooves corresponding to the positions of the guide sliding grooves are symmetrically arranged at the front and back ends of the execution plate, the connecting plates are in sliding butt joint in the limit sliding grooves, and two supporting spring rods are symmetrically arranged on opposite sides of the supporting plate and the connecting plates in a bilateral symmetry way.

Preferably, the cleaning assembly comprises a forward and reverse rotation motor, a gear, a positioning rack and a cleaning column, wherein: the upper end of the linkage plate on the upper side of the rotary cylinder is provided with a forward and reverse rotating motor through a motor seat, an output shaft of the forward and reverse rotating motor is connected with the rotary cylinder, a gear is fixedly installed between the rotary cylinder and the linkage plate on the upper end of the rotary cylinder, the gear is rotationally connected with the linkage plate, a positioning rack meshed with the gear is installed at the lower end of the bearing plate above the rotary cylinder from left to right, and a plurality of cleaning columns are uniformly arranged on the outer wall of the rotary cylinder from top to bottom and in the circumferential direction.

Preferably, the cleaning column comprises a positioning cylinder, a telescopic cylinder, a top extension spring and an adsorption ball, wherein: the outer wall of rotary drum is provided with flexible section of thick bamboo through the positioning tube, and the absorption ball is installed to the one end that the positioning tube was kept away from to flexible section of thick bamboo, and a plurality of absorption holes have been seted up to absorption ball outer wall circumference, and the junction of absorption ball and flexible section of thick bamboo is provided with the protection through detachable mode and fills up, and positioning tube, flexible section of thick bamboo and absorption ball are linked together, installs the top between positioning tube and the absorption ball and stretches the spring, and the top stretches the spring housing and establishes in the outside of flexible section of thick bamboo and not take place to contact with flexible section of thick bamboo.

Preferably, the installation groove has been seted up to inside the rotary cylinder and near its upside, is provided with the aspiration pump in the installation groove, and the connecting pipe is installed to the end of breathing in of aspiration pump, and the one section that the aspiration pump was kept away from to the connecting pipe extends to the lower extreme inner wall of rotary cylinder, and a plurality of trachea that pass behind the rotary cylinder are linked together with the positioning cylinder are installed to the outer wall of connecting pipe.

Preferably, the U-shaped plate is close to one side of the rotary drum and is provided with a collecting cavity, the lower end of the collecting cavity is of a V-shaped structure, one side of the collecting cavity, which is close to the rotary drum, is provided with a baffle, gaps corresponding to the positions of the cleaning columns are formed in the left side and the right side of the baffle at equal intervals from top to bottom, and a plurality of brushes corresponding to the positions of the gaps are arranged in the collecting cavity at equal intervals from top to bottom relative to one side of the rotary drum.

Preferably, the upper end of backup pad front and back symmetry articulates there are two first baffles, and the lower extreme front and back symmetry of connecting plate articulates there are two second baffles, from left to right equidistant a plurality of damping springs that are provided with between the first baffle and the second baffle of backup pad same side.

Preferably, the support frame is installed to the lower extreme of air energy heat pump body, and the support frame is located the one side that the jacking board is close to the execution board middle part, and the support frame is linked together with the through-hole, and the support frame lower extreme bilateral symmetry is provided with two air discharge fans.

3. The beneficial effects are that: 1. according to the improved air energy heat pump provided by the utility model, the supporting point of the supporting plate can be changed by adjusting the position of the damping piece, so that the supporting area of the air energy heat pump body can be adjusted, the stability of the air energy heat pump body in the use process is ensured, and in addition, the air energy heat pump body can be buffered by the supporting spring rod and the damping spring, so that the vibration amplitude of the air energy heat pump body in the working process is reduced, and the air energy heat pump body is prevented from being damaged due to vibration.

2. According to the filter unit provided by the utility model, the impurities on the outer wall of the mesh cover are adsorbed by the adsorption balls, then the rotary drum drives the adsorption balls adsorbed with the impurities to rotate into the collecting cavity, and then the impurities on the surface of the adsorption balls are brushed into the collecting cavity by the hairbrushes, so that the adsorption holes are prevented from being blocked by the impurities to influence the reutilization of the adsorption balls, the outer wall of the mesh cover can be cleaned, and the influence on the air permeability of the mesh cover caused by the impurities attached to the outer wall of the mesh cover is avoided.

3. According to the utility model, the exhaust fan can exhaust the heat in the air energy heat pump body, so that the conditions of damage and the like caused by overheat in the air energy heat pump body are prevented.

4. According to the air-source heat pump body, the air-source net frame can be protected through the net hole cover, sundries in the air are prevented from penetrating through the air-source net frame and drilling into the air-source heat pump body, and therefore the air-source heat pump body is ensured to be used normally.

Drawings

The utility model will be further described with reference to the drawings and examples.

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

Fig. 2 is a front view of the present utility model.

Fig. 3 is a schematic perspective view of the supporting unit of the present utility model.

Fig. 4 is a schematic perspective view of the base and the shock absorbing member of the present utility model.

Fig. 5 is a partial cutaway view of the air-source heat pump body and filter unit of the present utility model.

Fig. 6 is a partial cutaway view of a filter unit of the present utility model.

Fig. 7 is a partial enlarged view of fig. 6 at S in accordance with the present utility model.

Fig. 8 is a cross-sectional view (along the longitudinal section of the rotary drum) of the rotary drum and cleaning assembly of the present utility model.

Reference numerals: 1. an air energy heat pump body; 11. a breathable net frame; 2. a supporting unit; 21. a base; 23. a shock absorbing member; 231. a sliding block; 232. a bidirectional screw; 233. a support plate; 234. a connecting plate; 235. limiting sliding grooves; 236. supporting a spring rod; 237. a first baffle; 238. a second baffle; 239. a damping spring; 24. a performance board; 25. a jacking plate; 26. a support frame; 27. an exhaust fan; 3. a filtering unit; 31. a mesh cage; 32. a receiving plate; 33. a sliding groove; 34. a linkage plate; 35. a U-shaped plate; 351. a collection cavity; 352. a baffle; 353. a notch; 354. a brush; 36. a rotary drum; 361. an air extracting pump; 362. a connecting pipe; 363. an air pipe; 37. a cleaning assembly; 371. a forward and reverse rotation motor; 372. a gear; 373. positioning a rack; 374. cleaning the column; 375. a positioning cylinder; 376. a telescopic cylinder; 377. a top extension spring; 378. adsorption balls.

Detailed Description

Embodiments of the utility model are described in detail below with reference to the attached drawings, but the utility model can be implemented in a number of different ways, which are defined and covered by the claims.

An improved air-source heat pump according to an embodiment of the present utility model is described below with reference to the accompanying drawings. Referring to fig. 1 and 2, an improved air-source heat pump comprises an air-source heat pump body 1, a supporting unit 2 and a filtering unit 3, wherein a plurality of through holes are formed in the lower end of the air-source heat pump body 1 in a penetrating manner, and ventilation net frames 11 are symmetrically formed in the front and back of the outer wall of the air-source heat pump body 1.

Referring to fig. 1, 2 and 3, the supporting unit 2 includes a base 21, a guide chute, a shock absorbing member 23, an execution plate 24 and a jacking plate 25, wherein: the air energy heat pump comprises an air energy heat pump body 1, a base 21 is arranged below the air energy heat pump body 1, a plurality of supporting groups are arranged at equal intervals from left to right at the upper end of the base 21, each supporting group comprises two guide sliding grooves which are symmetrically arranged around the base 21, a damping piece 23 is arranged in each guide sliding groove, an execution plate 24 is arranged at the upper end of the damping piece 23 of the same supporting group, two jacking plates 25 are symmetrically arranged at the front and back of the upper end of the execution plate 24, and the upper ends of the jacking plates 25 are connected with the lower end of the air energy heat pump body 1; the support frame 26 is installed to the lower extreme of air energy heat pump body 1, and support frame 26 is located the side that jacking plate 25 is close to the middle part of execution board 24, and support frame 26 is linked together with the through-hole, and support frame 26 lower extreme bilateral symmetry is provided with two air discharge fans 27.

Referring to fig. 3 and 4, the shock absorbing member 23 includes a sliding block 231, a bidirectional screw 232, a support plate 233, a connection plate 234, a limit chute 235, and a support spring rod 236, wherein: a sliding block 231 is slidably arranged in the guide sliding groove, a plurality of bidirectional screws 232 corresponding to the positions of the supporting groups are rotatably arranged on the base 21 at equal intervals from left to right, the plurality of bidirectional screws 232 are connected through belt transmission, the bidirectional screws 232 penetrate through the sliding block 231 in a threaded fit mode, a supporting plate 233 is arranged at the upper end of the sliding block 231, limit sliding grooves 235 corresponding to the positions of the guide sliding grooves are symmetrically arranged at the front and back of the lower end of the execution plate 24, a connecting plate 234 is slidably butted in the limit sliding grooves 235, two supporting spring rods 236 are symmetrically arranged at the opposite sides of the supporting plate 233 and the connecting plate 234, supporting force pointing to the air energy heat pump body 1 is always applied to the connecting plate 234 by the supporting spring rods 236, and when the connecting plate 234 is subjected to external force, the supporting spring rods 236 can be elastically deformed; the upper end of the supporting plate 233 is symmetrically hinged with two first baffle plates 237 in front and back, the lower end of the connecting plate 234 is symmetrically hinged with two second baffle plates 238 in front and back, and a plurality of damping springs 239 are arranged between the first baffle plates 237 and the second baffle plates 238 on the same side of the supporting plate 233 at equal intervals from left to right; the damper spring 239 always applies a jacking force to the first barrier 237 and the second barrier 238, and when the first barrier 237 is pressurized, the damper spring 239 can be elastically deformed.

In this embodiment, the support force can be applied to the air-source heat pump body 1 by the execution plate 24 through the lifting plate 25, so that adjusting the positions of the shock absorbing members 23 can change the supporting points of the support plate 233, and if the weights of the air-source heat pump bodies 1 are different, the distance between the two shock absorbing members 23 at the lower end of the support plate 233 needs to be increased or decreased, so that the supporting area of the air-source heat pump body 1 is adjusted, and the adjustment of the distance between the shock absorbing members 23 is performed as follows.

The bidirectional screw rod 232 is rotated, the sliding blocks 231 on the front side and the rear side of the bidirectional screw rod 232 can be driven to move oppositely or move oppositely while rotating, the sliding blocks 231 drive the supporting plate 233, the supporting spring rod 236 and the connecting plate 234 to integrally move so as to adjust the position of the connecting plate 234 in the limiting sliding groove 235, thereby being capable of adjusting the supporting point of the connecting plate 234 to the executing plate 24, further adjusting the supporting area of the air energy heat pump body 1 and ensuring the stability of the air energy heat pump body 1 in the use process; in addition, through supporting spring bar 236 and damping spring 239 can cushion air-source heat pump body 1 to reduce the vibrations range of air-source heat pump body 1 in the course of the work, thereby prevent that air-source heat pump body 1 from taking place the damage because of vibrations, simultaneously, start air discharge fan 27, can discharge the inside heat of air-source heat pump body 1 through air discharge fan 27, thereby prevent that air-source heat pump body 1 from inside overheated and the condition such as damage appears.

Referring to fig. 1, 5 and 6, the filter unit 3 includes a screen mask 31, a receiving plate 32, a sliding groove 33, a linkage plate 34, a U-shaped plate 35, a rotary cylinder 36 and a cleaning assembly 37, wherein: the outer wall of the air energy heat pump body 1 is provided with two mesh covers 31 in a front-back symmetrical mode in a detachable mode, a plurality of conical holes are formed in the mesh covers 31 in a penetrating mode in a matrix arrangement mode, the diameters of the conical holes gradually decrease from the mesh covers 31 to one side close to the middle of the air energy heat pump body, the mesh covers 31 are sleeved outside the ventilation mesh frame 11, the ventilation mesh frame 11 can be protected through the mesh covers 31, sundries in air are prevented from penetrating through the ventilation mesh frame 11 and drilling into the air energy heat pump body 1, normal use of the air energy heat pump body 1 is ensured, sundries in air are accumulated in the conical holes in the outer wall of the mesh covers 31, two bearing plates 32 are symmetrically installed on the front side wall and the rear side wall of the air energy heat pump body 1 in an up-down mode, sliding grooves 33 are formed in a penetrating mode on the bearing plates 32, U35 are jointly installed on one side, away from the mesh covers 31, of the two corresponding side of the air energy heat pump body 1, of the two corresponding side of the two bearing plates 34 are jointly installed, and a rotary drum 36 is installed inside a rotary drum 37 assembly is installed.

Referring to fig. 6, 7 and 8, the cleaning assembly 37 includes a forward and reverse motor 371, a gear 372, a positioning rack 373 and a cleaning post 374, wherein: the upper end of a linkage plate 34 on the upper side of the rotary drum 36 is provided with a forward and reverse rotation motor 371 through a motor seat, an output shaft of the forward and reverse rotation motor 371 is connected with the rotary drum 36, a gear 372 is fixedly arranged between the rotary drum 36 and the linkage plate 34 on the upper end of the rotary drum, the gear 372 is rotationally connected with the linkage plate 34, a positioning rack 373 meshed with the gear 372 is arranged at the lower end of a receiving plate 32 above the rotary drum 36 from left to right, a plurality of cleaning columns 374 are uniformly arranged on the outer wall of the rotary drum 36 from top to bottom in the circumferential direction, a collecting cavity 351 is arranged on one side of the U-shaped plate 35, close to the rotary drum 36, the lower end of the collecting cavity 351 is of a V-shaped structure, sundries are conveniently guided to the bottom of the collecting cavity 351 through the V-shaped structure, a baffle 352 is arranged on one side of the collecting cavity 351, notches 353 corresponding to the positions of the cleaning columns 374 are uniformly arranged on the left and right side of the baffle 352 from top to bottom, a plurality of brushes 354 corresponding to the positions of the notches 353 are uniformly arranged on one side of the collecting cavity 351, relative to the rotary drum 36, from top to bottom; the cleaning post 374 is comprised of a positioning cylinder 375, a telescoping cylinder 376, a push spring 377 and an adsorption ball 378, wherein: the outer wall of rotary drum 36 is provided with flexible section of thick bamboo 376 through locating cylinder 375, flexible section of thick bamboo 376 is flexible under the exogenic action, the absorption ball 378 is installed to the one end that flexible section of thick bamboo 376 kept away from locating cylinder 375, absorption ball 378 is convenient for dismantle's mosaic structure, so that pour out its inside dust, a plurality of absorption holes have been seted up to absorption ball 378 outer wall circumference, and the junction of absorption ball 378 and flexible section of thick bamboo 376 is provided with the protection pad through detachable mode, can prevent through the protection pad that the inside dust of absorption ball 378 from inhaling in flexible section of thick bamboo 376, and then avoid the dust to bore into aspiration pump 361 after flexible section of thick bamboo 376, locating cylinder 375 and the back and influence the normal operation of aspiration pump 361, locating cylinder 375, flexible section of thick bamboo 376 and absorption ball 378 are linked together, install top between locating cylinder 375 and the absorption ball 378 and stretch spring 377, top stretch spring 377 cover is established in the outside of flexible section of thick bamboo 376 and is not contacted with flexible section of thick bamboo 376 all the time, top stretch spring 377 exerts the extrusion force that points to keeping away from locating cylinder 375 one side to the absorption ball.

Referring to fig. 8, a mounting groove is formed in the rotary cylinder 36 and close to the upper side of the rotary cylinder, an air pump 361 is arranged in the mounting groove, a connecting pipe 362 is arranged at the air suction end of the air pump 361, a section of the connecting pipe 362 away from the air pump 361 extends to the inner wall of the lower end of the rotary cylinder 36, and a plurality of air pipes 363 which are communicated with the positioning cylinder 375 after penetrating through the rotary cylinder 36 are arranged on the outer wall of the connecting pipe 362.

After the air-source heat pump body 1 is used for a period of time, impurities such as dust are easily attached to the outer wall of the mesh cover 31, and ventilation of the air-source heat pump body 1 is easily affected, so that cleaning treatment is required to be performed on the mesh cover 31 regularly, and specific cleaning steps are as follows: firstly, the suction pump 361 is started, the suction pump 361 pumps air to the adsorption balls 378 through the connecting pipe 362 and the air pipe 363, then the forward and backward motor 371 is started, the forward and backward motor 371 drives the rotary drum 36 and the gear 372 to rotate forward and backward, the gear 372 drives the rotary drum 36 to reciprocate left and right under the action of the positioning rack 373, during the period, the rotary drum 36 drives the adsorption balls 378 to abut against the tapered holes through the positioning drum 375, the telescopic drum 376 and the jacking spring 377, the adsorption balls 378 suck dust and granular impurities into the adsorption balls 378 through the adsorption holes on the outer walls of the adsorption balls 378, and impurities with larger volume are attached to the outer walls of the adsorption balls 378 under the action of suction, then the rotary drum 36 drives the adsorption balls 378 with impurities to move out of the outer walls of the mesh cover 31 and rotate into the collecting cavity 351 through the positioning drum 375 and the telescopic drum 376, and the adsorption balls 378 are contacted with the hairbrushes 354 under the action of the jacking spring 377, so that impurities on the surfaces of the adsorption balls 378 are brushed inside the collecting cavity 351 through the hairbrushes 354, the adsorption balls are prevented from being influenced by the adsorption holes, the adsorption balls 378 are reused, the impurities can be prevented from being influenced by the adsorption holes, the outer walls of the mesh cover 31 can be cleaned, and the impurities can be prevented from being adhered to the outer walls of the mesh cover 31.

The working process of the utility model is as follows: s1: the bidirectional screw 232 is rotated, the bidirectional screw 232 drives the sliding blocks 231 on the front side and the rear side of the bidirectional screw 232 to move in opposite directions or move in opposite directions, the sliding blocks 231 drive the supporting plate 233, the supporting spring rod 236 and the connecting plate 234 to move integrally so as to adjust the position of the connecting plate 234 in the limiting sliding groove 235, thereby adjusting the supporting area of the air energy heat pump body 1, ensuring the stability of the air energy heat pump body 1 in the use process, and buffering the air energy heat pump body 1 through the supporting spring rod 236 and the damping spring 239 so as to reduce the vibration amplitude of the air energy heat pump body 1 in the working process.

S2: the exhaust fan 27 is started, and the heat in the air-source heat pump body 1 can be discharged through the exhaust fan 27, so that the conditions of damage and the like caused by overheat in the air-source heat pump body 1 are prevented.

S3: starting the sucking pump 361, sucking the adsorption ball 378 through the connecting pipe 362 and the air pipe 363 by the sucking pump 361, then starting the forward and reverse rotating motor 371, driving the rotary cylinder 36 and the gear 372 to reciprocate forward and reverse, driving the rotary cylinder 36 to reciprocate left and right by the gear 372 under the action of the positioning rack 373, driving the adsorption ball 378 to abut against the conical hole by the rotary cylinder 36, enabling the adsorption ball 378 to suck dust and granular impurities into the adsorption ball 378 through the adsorption hole on the outer wall of the adsorption ball 378, and enabling the impurities with larger volume to abut against the outer wall of the adsorption ball 378 under the action of suction force.

S4: the rotary drum 36 drives the adsorption ball 378 adsorbed with impurities to move out from the outer wall of the mesh hood 31 and rotate into the collection cavity 351, the adsorption ball 378 contacts with the hairbrush 354, impurities on the surface of the adsorption ball 378 are brushed out into the collection cavity 351 by the hairbrush 354, and therefore the outer wall of the mesh hood 31 can be cleaned, and the influence of impurities attached to the outer wall of the mesh hood 31 and the air permeability of the mesh hood is avoided.

The above description is only of the preferred embodiments of the present utility model and is not intended to limit the present utility model, but various modifications and variations can be made to the present utility model by those skilled in the art. Any modification, equivalent replacement, improvement, etc. made within the spirit and principle of the present utility model should be included in the protection scope of the present utility model.

Claims

1. An improved air energy heat pump, comprising:

the air energy heat pump comprises an air energy heat pump body (1), wherein a plurality of through holes are formed in the lower end of the air energy heat pump body (1) in a penetrating mode, and ventilation net frames (11) are symmetrically formed in the front and the back of the outer wall of the air energy heat pump body (1);

the support unit (2), the support unit (2) includes base (21), direction spout, bolster (23), executive plate (24) and jacking board (25), wherein: the air energy heat pump comprises an air energy heat pump body (1), and is characterized in that a base (21) is arranged below the air energy heat pump body (1), a plurality of supporting groups are arranged at equal intervals from left to right at the upper end of the base (21), each supporting group comprises two guide sliding grooves which are symmetrically distributed around the base (21), a damping piece (23) is arranged in each guide sliding groove, an execution plate (24) is arranged at the upper end of the damping piece (23) of the same supporting group, two jacking plates (25) are symmetrically arranged at the front and back of the upper end of the execution plate (24), and the upper ends of the jacking plates (25) are connected with the lower end of the air energy heat pump body (1);

the filter unit (3), filter unit (3) include that net hole cover (31), accept board (32), sliding tray (33), linkage board (34), U-shaped board (35), rotary drum (36) and clean subassembly (37), wherein: the outer wall of the air energy heat pump body (1) is provided with two mesh covers (31) in a front-back symmetrical mode in a detachable mode, a plurality of conical holes are formed in the mesh covers (31) in a penetrating mode in a matrix arrangement mode, the diameters of the conical holes gradually decrease from the mesh covers (31) to one side close to the middle of the air energy heat pump body, the mesh covers (31) are sleeved outside the ventilation mesh frame (11), two bearing plates (32) are symmetrically arranged on the front side wall and the rear side wall of the air energy heat pump body (1) in an up-down symmetrical mode relative to the mesh covers (31), sliding grooves (33) are formed in the bearing plates (32) in a penetrating mode, a linkage plate (34) is connected in a sliding mode in the sliding grooves (33), a U-shaped plate (35) is jointly arranged on one side, away from the mesh covers (31), of the two linkage plates (34) on the same side of the air energy heat pump body (1), a rotary drum (36) is rotatably arranged on the opposite side, and a cleaning assembly (37) is arranged inside the rotary drum (36);

the damping piece (23) comprises a sliding block (231), a bidirectional screw (232), a supporting plate (233), a connecting plate (234), a limiting sliding groove (235) and a supporting spring rod (236), wherein: the utility model discloses a support spring device, including base (21), support group, support plate (234), guide chute is interior slip and is provided with slider (231), equidistant rotation from left to right is provided with a plurality of bi-directional screw rods (232) corresponding with support group position on base (21), a plurality of bi-directional screw rods (232) are connected through the belt drive, bi-directional screw rods (232) pass slider (231) through screw-thread fit's mode, support plate (233) are installed to the upper end of slider (231), limit chute (235) corresponding with guide chute position has been seted up to the lower extreme front and back symmetry of executive plate (24), limit chute (235) slip butt joint has connecting plate (234), the opposite side bilateral symmetry of support plate (233) and connecting plate (234) is provided with two support spring bars (236).

2. An improved air-source heat pump as set forth in claim 1 wherein: the cleaning assembly (37) comprises a forward and reverse rotation motor (371), a gear (372), a positioning rack (373) and a cleaning column (374), wherein: the upper end of a linkage plate (34) at the upper side of the rotary cylinder (36) is provided with a forward and reverse motor (371) through a motor seat, an output shaft of the forward and reverse motor (371) is connected with the rotary cylinder (36), a gear (372) is fixedly arranged between the rotary cylinder (36) and the linkage plate (34) at the upper end thereof, the gear (372) is rotationally connected with the linkage plate (34), a positioning rack (373) meshed with the gear (372) is arranged at the lower end of the bearing plate (32) above the rotary cylinder (36) from left to right, and a plurality of cleaning columns (374) are uniformly arranged on the outer wall of the rotary cylinder (36) from top to bottom and circumferentially.

3. An improved air energy heat pump according to claim 2, wherein: the cleaning column (374) is composed of a positioning cylinder (375), a telescopic cylinder (376), a top extension spring (377) and an adsorption ball (378), wherein: the outer wall of rotary drum (36) is provided with flexible section of thick bamboo (376) through locating cylinder (375), and absorption ball (378) are installed to the one end that locating cylinder (375) was kept away from to flexible section of thick bamboo (376), and a plurality of absorption holes have been seted up to absorption ball (378) outer wall circumference, and the junction of absorption ball (378) and flexible section of thick bamboo (376) is provided with the protection pad through detachable mode, and locating cylinder (375), flexible section of thick bamboo (376) and absorption ball (378) are linked together, install top between locating cylinder (375) and the absorption ball (378) and stretch spring (377), top stretch spring (377) cover establish in the outside of flexible section of thick bamboo (376) and do not take place to contact with flexible section of thick bamboo (376).

4. An improved air-source heat pump as set forth in claim 1 wherein: the rotary cylinder (36) is internally provided with a mounting groove close to the upper side of the rotary cylinder, an air suction pump (361) is arranged in the mounting groove, a connecting pipe (362) is arranged at the air suction end of the air suction pump (361), one section of the connecting pipe (362) away from the air suction pump (361) extends to the inner wall of the lower end of the rotary cylinder (36), and a plurality of air pipes (363) which penetrate through the rotary cylinder (36) and are communicated with the positioning cylinder (375) are arranged on the outer wall of the connecting pipe (362).

5. An improved air-source heat pump as set forth in claim 1 wherein: the utility model discloses a cleaning device, including U-shaped board (35), rotary drum (36), baffle (352) are installed to one side that U-shaped board (35) is close to rotary drum (36), and collection cavity (351)'s lower extreme is V-arrangement structure, and collection cavity (351) are close to rotary drum (36) one side, and breach (353) corresponding with cleaning post (374) position are all equidistant from the top down seted up in the left and right sides of baffle (352), and a plurality of brush (354) corresponding with breach (353) position are installed to collection cavity (351) for one side from the top down equidistant of rotary drum (36).

6. An improved air-source heat pump as set forth in claim 1 wherein: two first baffles (237) are symmetrically hinged to the upper end of the supporting plate (233), two second baffles (238) are symmetrically hinged to the lower end of the connecting plate (234), and a plurality of damping springs (239) are arranged between the first baffles (237) and the second baffles (238) on the same side of the supporting plate (233) at equal intervals from left to right.

7. An improved air-source heat pump as set forth in claim 1 wherein: the lower extreme of air-source heat pump body (1) is installed support frame (26), and support frame (26) are located one side in the middle part of jacking board (25) is close to execution board (24), and support frame (26) are linked together with the through-hole, and support frame (26) lower extreme bilateral symmetry is provided with two air discharge fans (27).