CN115307194A - Ultralow-temperature air source heat pump for heating residents - Google Patents

Abstract

The invention relates to the field of air source heat pumps, in particular to an ultralow-temperature air source heat pump for heating residents. The invention provides an ultralow-temperature air source heat pump for heating residents, which can be used for damping an air source heat pump. An ultra-low temperature air source heat pump for heating residents comprises a heat pump body; the upper part of the heat pump body is connected with a detachable cover plate; the front side and the rear side of the lower part of the heat pump body are both connected with two first sliding blocks in a sliding manner; the bottoms of the four first sliding blocks are connected with the bottom in the heat pump body through first springs; the heat pump device supporting plate is placed on the four first sliding blocks. According to the invention, the heat pump device supporting plate is placed on the first sliding block, and under the action of the first spring, the first sliding block can enable the air source heat pump to have a good damping effect when the air source heat pump works, so that the heat pump device is prevented from being damaged due to severe vibration when the air source heat pump works.

Description

Ultralow-temperature air source heat pump for heating residents

Technical Field

The invention relates to the field of air source heat pumps, in particular to an ultralow-temperature air source heat pump for heating residents.

Background

The ultra-low temperature air source heat pump is a device for heating or supplying hot water by taking air as a low-grade heat source, and can also perform refrigeration in summer, the air source heat pump unit is composed of four main components, namely a compressor, a condenser, a throttle valve and an evaporator, but the existing air source heat pump can generate certain vibration when working, so that devices in the air source heat pump collide due to the vibration, the devices in the air source heat pump are easily damaged, and the working efficiency of the heat pump is influenced when the existing air source heat pump works.

In summary, an ultra-low temperature air source heat pump for heating residents, which can damp an air source heat pump, needs to be developed.

Disclosure of Invention

Aiming at overcoming the defects that the existing air source heat pump can generate vibration during working and can damage devices seriously, the invention provides the ultralow-temperature air source heat pump for heating residents, which can absorb shock for the air source heat pump.

In order to achieve the above purpose, the invention is realized by the following scheme: an ultra-low temperature air source heat pump for heating residents comprises:

a heat pump body;

the upper part of the heat pump body is connected with a detachable cover plate;

the front side and the rear side of the lower part of the heat pump body are both connected with two first sliding blocks in a sliding manner;

the bottoms of the four first sliding blocks are connected with the bottom in the heat pump body through first springs;

the four first sliding blocks are provided with heat pump device supporting plates, and the heat pump devices are arranged on the heat pump device supporting plates;

the heat pump device clamping mechanism is connected between the heat pump device supporting plate and the first sliding block and used for limiting the heat pump device supporting plate, the heat pump device supporting plate moves downwards to be in contact with the heat pump device clamping mechanism, the heat pump device clamping mechanism clamps the heat pump device supporting plate, and meanwhile, the heat pump device clamping mechanism is clamped in the first sliding block to limit the heat pump device supporting plate, so that the device is prevented from being damaged due to over severe vibration generated during working of the heat pump device;

the heat pump device stabilizing mechanism is connected to the lower portion of the heat pump body and used for clamping the heat pump device, and the heat pump device stabilizing mechanism moves towards the inner side to clamp the heat pump device, so that the heat pump device is prevented from loosening during working.

As the improvement of the proposal, the heat pump device clamping mechanism comprises:

the left side and the right side of the lower parts of the four first sliding blocks are connected with the arc plates for clamping the heat pump device supporting plate, and the middle parts of the four first sliding blocks are provided with clamping holes;

the heat pump device supporting plate is clamped through the arc-shaped plate, and the clamping blocks are clamped into the clamping holes, so that the heat pump device is prevented from excessively violent vibration during working;

and the second springs are connected between the inner sides of the four clamping blocks and the heat pump device supporting plate.

As an improvement of the scheme, the heat pump device stabilizing mechanism comprises:

the left side and the right side of the lower side in the heat pump body are both connected with two second sliding blocks in a sliding manner;

the clamping plate is connected to the upper left side of the two second sliding blocks on the left side, the clamping plate used for clamping the heat pump device is connected to the upper right side of the two second sliding blocks on the right side, the heat pump device is clamped by moving the clamping plate to the inner side, and the heat pump device is prevented from loosening during working;

and a third spring is connected between the inner sides of the lower parts of the four second sliding blocks and the heat pump body.

As the improvement of the proposal, the device also comprises an opening mechanism for pushing the fixture block to be separated from the fixture hole, and the opening mechanism comprises:

the four first sliding blocks are connected with the clamping holes of the four first sliding blocks in a sliding manner, and the four first sliding blocks are connected with the clamping holes of the four first sliding blocks in a sliding manner;

the clamping block is pressed inwards by driving the concave connecting rods through pressing the pressing rods, and the pressing rods are used for driving the clamping blocks to be separated from the clamping holes;

and the outer sides of the four concave connecting rods are sleeved with the fourth springs, and two ends of each fourth spring are respectively connected with the pressing rod and the first sliding block.

As an improvement of the above scheme, the heat pump device stabilizing mechanism further comprises a heat pump device stabilizing mechanism for stabilizing the heat pump device supporting plate, and the heat pump device stabilizing mechanism comprises:

the left side and the right side inside the heat pump device supporting plate are connected with the wedge-shaped clamping blocks in a sliding manner;

the left side and the right side inside the heat pump device supporting plate are respectively sleeved with a fifth spring, and two ends of the fifth spring are respectively connected with the wedge-shaped clamping block and the heat pump device supporting plate;

the lower part in the heat pump body is connected with the stabilizing plate in a sliding mode, the wedge-shaped clamping block is driven to move downwards through the heat pump device supporting plate to clamp the stabilizing plate, and the heat pump device is prevented from being damaged due to severe vibration;

the middle part of the stabilizing plate is sleeved with four stabilizing springs, and two ends of the four stabilizing springs are respectively connected with the stabilizing plate and the heat pump body.

As an improvement of the above scheme, the heat pump device further comprises a closing mechanism for automatically closing the heat pump device, wherein the closing mechanism comprises:

the right lower side of the right wedge-shaped clamping block is connected with the L-shaped connecting rod;

the front side of the top of the L-shaped connecting rod is connected with the L-shaped rack;

the right front side of the heat pump device is rotatably connected with a water outlet valve;

the gear is connected to the water outlet valve and meshed with the L-shaped rack, the L-shaped connecting rod is driven to move left and right through the wedge-shaped clamping block to drive the L-shaped rack to move left and right, and the L-shaped rack drives the gear to rotate forward and backward to drive the water outlet valve to be automatically closed and opened.

As the improvement of above-mentioned scheme, still including being used for compressing tightly spacing heat pump device hold-down mechanism to heat pump device, heat pump device hold-down mechanism including:

the top of the cover plate is connected with the U-shaped pressing plate in a sliding manner;

the bottom of the U-shaped pressing plate and the top of the cover plate are connected with a sixth spring;

sponge briquetting, both sides all bond around the U-shaped clamp plate bottom and are used for compressing tightly spacing sponge briquetting to the heat pump device, and sponge briquetting and heat pump device contact are used for compressing tightly spacing to the heat pump device, and the power that resets through the sixth spring drives the U-shaped clamp plate and moves down, and the U-shaped clamp plate drives the sponge briquetting and compresses tightly the heat pump device all the time, prevents that the heat pump device from taking place violent vibrations and apron bump.

As the improvement of above-mentioned scheme, the even interval in both sides is connected with the rubber strip about the U-shaped clamp plate for increase the frictional force between U-shaped clamp plate and the apron, prevent that the heat pump device can become flexible when the violent vibrations of heat pump device.

The invention has at least one of the following advantages: according to the invention, the heat pump device supporting plate is placed on the first sliding block, and under the action of the first spring, the first sliding block can enable the air source heat pump to have a good damping effect during working, so that the heat pump device is prevented from being damaged due to severe vibration during working; the pressing rod is pressed towards the inner side to drive the concave connecting rod to push the clamping block to move towards the inner side to be separated from the clamping hole, so that the clamping block is separated from the clamping hole without tools, and the operation is simpler; the heat pump device supporting plate drives the wedge-shaped clamping block to move downwards to clamp the stabilizing plate, so that the heat pump device supporting plate can be fixed, and the device is prevented from being damaged when the heat pump device shakes violently, and economic loss is avoided; the wedge-shaped clamping block drives the L-shaped connecting rod and the L-shaped rack to move towards the right side, so that the gear and the water outlet valve are driven to rotate, the water outlet valve can be automatically closed, and the closing is not required to be manually controlled by a worker; under the effect of sixth spring for the sponge briquetting compresses tightly the heat pump device all the time, prevents that the heat pump device from shaking about can and lapping the bump when violent vibrations, thereby damages the heat pump device.

Drawings

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

Fig. 2 is a partial perspective view of the present invention.

Fig. 3 is a schematic perspective view of the basic principal of the present invention.

Fig. 4 is a schematic perspective view of a heat pump device clamping mechanism according to the present invention.

Fig. 5 is a partial perspective view of the heat pump device clamping mechanism of the present invention.

Fig. 6 is a schematic perspective view of a first securing mechanism of a heat pump device according to the present invention.

Fig. 7 is a schematic perspective view of a second securing mechanism of a heat pump device according to the present invention.

Fig. 8 is a perspective view of the opening mechanism of the present invention.

Fig. 9 is a schematic perspective view of a first stabilizing mechanism of the heat pump device of the present invention.

Fig. 10 is a schematic perspective view of a second heat pump device stabilizing mechanism according to the present invention.

Fig. 11 is a schematic perspective view of a first closing mechanism of the present invention.

Fig. 12 is a schematic perspective view of a second embodiment of the closure mechanism of the present invention.

Fig. 13 is a schematic perspective view of a heat pump device pressing mechanism according to the present invention.

Fig. 14 is a schematic sectional perspective view of a heat pump device pressing mechanism according to the present invention.

FIG. 15 is an enlarged perspective view of the present invention at A.

Labeled as: 1-a heat pump body, 2-a cover plate, 3-a heat pump device supporting plate, 4-a first sliding block, 5-a first spring, 6-a heat pump device clamping mechanism, 61-an arc plate, 62-a clamping block, 63-a second spring, 7-a heat pump device stabilizing mechanism, 71-a second sliding block, 72-a third spring, 73-a clamping plate, 8-an opening mechanism, 81-a pressing rod, 82-a fourth spring, 83-a concave connecting rod, 9-a heat pump device stabilizing mechanism, 91-a wedge-shaped clamping block, 92-a fifth spring, 93-a stabilizing plate, 94-a stabilizing spring, 10-a closing mechanism, 101-an L-shaped connecting rod, 102-an L-shaped rack, 103-a water outlet valve, 104-a gear, 11-a heat pump device pressing mechanism, 1101-a U-shaped pressing plate, 1102-a sixth spring and 1103-a sponge pressing block.

Detailed Description

The invention is described in detail below with reference to the drawings and specific examples, but the invention is not limited thereto.

Example 1

An ultra-low temperature air source heat pump for heating residents is disclosed, as shown in figures 1-7, and comprises a heat pump body 1, a cover plate 2, a heat pump device supporting plate 3, a first slide block 4, a first spring 5, a heat pump device clamping mechanism 6, an arc-shaped plate 61, a clamping block 62, a second spring 63, a heat pump device stabilizing mechanism 7, a second slide block 71, a third spring 72 and a clamping plate 73, wherein the upper part of the heat pump body 1 is connected with the detachable cover plate 2 through bolts, the front side and the rear side of the lower part of the heat pump body 1 are both connected with two first slide blocks 4 in a sliding way, the bottoms of the four first slide blocks 4 are both connected with the first spring 5 with the inner bottom of the heat pump body 1, the heat pump device supporting plate 3 is arranged on the four first slide blocks 4, a heat pump device is arranged on the heat pump device supporting plate 3, the air source heat pump generally comprises a compressor, a condenser, a throttle valve and an evaporator, the heat pump device clamping mechanism 6 is connected between the heat pump device supporting plate 3 and the first slide blocks 4, the heat pump device clamping mechanism 6 is used for limiting the heat pump device supporting plate 3, the lower part of the heat pump body 1 is connected with the heat pump device stabilizing mechanism 7, the heat pump device stabilizing mechanism 7 is used for clamping a heat pump device, the left side and the right side of the lower part of each of the four first sliding blocks 4 are welded with the arc-shaped plates 61, the arc-shaped plates 61 are used for clamping the heat pump device supporting plate 3, eight arc-shaped plates 61 are arranged, the middle parts of the four first sliding blocks 4 are provided with clamping holes, the front side and the rear side of the lower part in the heat pump device supporting plate 3 are connected with two clamping blocks 62 in a sliding manner, the clamping blocks 62 are used for limiting the heat pump device supporting plate 3, the four clamping blocks 62 are respectively clamped with the adjacent clamping holes after sliding, the inner sides of the four clamping blocks 62 are connected with the heat pump device supporting plate 3 through second springs 63, the left side and the right side of the lower side in the heat pump body 1 are connected with two second sliding blocks 71, the left upper sides of the two left second sliding blocks 71 are welded with clamping plates 73, the right upper sides of the two right second sliding blocks 71 are welded with clamping plates 73, the clamping plates 73 are used for clamping heat pump devices, and third springs 72 are connected between the inner sides of the lower portions of the four second sliding blocks 71 and the heat pump body 1.

When the air source heat pump device damping device is used, a heat pump device is placed on a heat pump device supporting plate 3, then a cover plate 2 is detached, the heat pump device supporting plate 3 is placed on a first sliding block 4, a clamping plate 73 is pulled towards the outer side to drive a second sliding block 71 to move towards the outer side, at the same time, a third spring 72 is stretched, then the heat pump device supporting plate 3 is placed on the first sliding block 4, the air source heat pump can play a good damping effect when the air source heat pump works through the first sliding block 4, meanwhile, the heat pump device supporting plate 3 is in contact with an arc-shaped plate 61, the heat pump device supporting plate 3 extrudes the arc-shaped plate 61 to open towards the outer side, meanwhile, the heat pump device supporting plate 3 is clamped and limited under the action of the arc-shaped plate 61, then the heat pump device is pressed to move downwards to drive the heat pump device supporting plate 3 and the first sliding block 4 to move downwards, at the moment, the first spring 5 is compressed, then the cover plate 2 is reset, meanwhile, the first slider 4 drives the clamping block 62 to move downwards, when the clamping block 62 moves downwards to be contacted with the clamping hole, the second spring 63 which is in a compressed state in the initial state is reset, the clamping block 62 is driven to move outwards and be clamped into the clamping hole, the purpose of limiting the first slider 4 is achieved, the heat pump device is prevented from being damaged by vibration generated when the heat pump device works, then the clamping plate 73 is loosened, the third spring 72 resets at the moment, the second slider 71 and the clamping plate 73 are driven to move inwards and reset, the heat pump device is clamped and limited by the clamping plate 73, the heat pump device is prevented from loosening when the heat pump device works, the stability is further improved, the device of the air source heat pump can be well stabilized through the clamping plate 73, when the air source heat pump device needs to be disassembled, the cover plate 2 is disassembled, the clamping block 62 is pushed to be separated from the clamping hole by means of a tool, the second spring 63 is compressed, and the first spring 5 resets at the same time, drive first slider 4 and heat pump device backup pad 3 and up move and reset, then take out heat pump device backup pad 3 for heat pump device backup pad 3 breaks away from arc 61, and arc 61 resets by oneself, and third spring 72 resets simultaneously, drives splint 73 and second slider 71 and moves to the inboard and resets can, then with apron 2 reset.

Example 2

On the basis of embodiment 1, as shown in fig. 1, fig. 2 and fig. 8, the opening mechanism 8 is further included, the opening mechanism 8 is configured to push the fixture block 62 to be separated from the fixture hole, the opening mechanism 8 includes a pressing rod 81, a fourth spring 82 and a concave connecting rod 83, the concave connecting rods 83 are slidably connected in the fixture holes of the four first sliders 4, the four concave connecting rods 83 respectively contact with the adjacent fixture blocks 62 after moving, the concave connecting rods 83 are configured to push the fixture blocks 62 to be separated from the fixture holes, the pressing rod 81 is welded to the front sides of the two concave connecting rods 83 on the front side, the pressing rod 81 is welded to the rear sides of the two concave connecting rods 83 on the rear side, the fourth spring 82 is sleeved on the outer sides of the four concave connecting rods 83, and both ends of the fourth spring 82 are respectively connected to the pressing rod 81 and the first slider 4. When needing to dismantle, press down the pressure lever 81 and press down to the inboard, press down lever 81 and drive concave connecting rod 83 and remove toward the inboard, fourth spring 82 is compressed this moment, make concave connecting rod 83 promote fixture block 62 and move and break away from with the card hole toward the inboard, so, just need not to make four fixture blocks 62 break away from with the card hole simultaneously with the help of the instrument, the operation is simpler, fixture block 62 breaks away from the back with the card hole, loosen and press down lever 81, fourth spring 82 resets this moment, drive concave connecting rod 83 and press down lever 81 and move to reset toward the outside.

As shown in fig. 1, fig. 2, fig. 9 and fig. 10, the heat pump device stabilizing mechanism 9 is further included, the heat pump device stabilizing mechanism 9 is used for stabilizing the heat pump device supporting plate 3, the heat pump device stabilizing mechanism 9 includes a wedge-shaped clamping block 91, a fifth spring 92, a stabilizing plate 93 and a stabilizing spring 94, the wedge-shaped clamping block 91 is slidably connected to the left and right sides inside the heat pump device supporting plate 3, the fifth spring 92 is sleeved on the left and right sides inside the heat pump device supporting plate 3, two ends of the fifth spring 92 are respectively connected with the wedge-shaped clamping block 91 and the heat pump device supporting plate 3, the stabilizing plate 93 is slidably connected to the inner lower portion of the heat pump body 1, the stabilizing plate 93 is clamped after the wedge-shaped clamping block 91 moves downwards and used for stabilizing the heat pump device supporting plate 3, four stabilizing springs 94 are sleeved on the middle portion of the stabilizing plate 93, and two ends of the four stabilizing springs 94 are respectively connected with the stabilizing plate 93 and the heat pump body 1. When violent vibration occurs to the heat pump device, it is described that the inside of the heat pump device breaks down, the violent vibration of the heat pump device drives the heat pump device supporting plate 3 to violently vibrate, the wedge-shaped clamping block 91 is driven to move downwards to be in contact with the stabilizing plate 93, the stabilizing plate 93 extrudes the wedge-shaped clamping block 91 to move towards the outer side, the fifth spring 92 is compressed at the moment, when the wedge-shaped clamping block 91 moves downwards to cross the stabilizing plate 93, the fifth spring 92 resets at the moment, the wedge-shaped clamping block 91 is driven to move inwards to clamp the stabilizing plate 93, the heat pump device supporting plate 3 is fixed, the device is prevented from being damaged when the violent vibration of the heat pump device occurs, economic loss is caused, the stabilizing spring 94 plays a buffering role, then a worker closes and stops working the heat pump device, the wedge-shaped clamping block 91 is manually pulled towards the outer side, the fifth spring 92 is compressed at the moment, the wedge-shaped clamping block 91 is separated from the stabilizing plate 93, the heat pump device supporting plate 3 drives the wedge-shaped clamping block 91 to move upwards to reset, then the wedge-shaped clamping block 91 is loosened, the maintenance of the wedge-shaped clamping block 92 to reset, the heat pump device is driven to move inwards, then the heat pump device is taken out, the heat pump device, and the heat pump device is repaired by the heat pump device, and the heat pump device is reset by the heat pump device, and the heat pump device is restored, and the heat pump device can be restored, and the heat pump device can be repaired again, and the device can be restored.

As shown in fig. 1, 2, 11 and 12, the heat pump device closing device further comprises a closing mechanism 10, the closing mechanism 10 is used for automatically closing the heat pump device, the closing mechanism 10 comprises an L-shaped connecting rod 101, an L-shaped rack 102, a water outlet valve 103 and a gear 104, the L-shaped connecting rod 101 is welded on the right lower side of the right wedge-shaped clamping block 91 on the right side, the L-shaped rack 102 is welded on the front side of the top of the L-shaped connecting rod 101, the water outlet valve 103 is rotatably connected on the right front side of the heat pump device, the gear 104 is connected on the water outlet valve 103, and the gear 104 is meshed with the L-shaped rack 102. When the heat pump device is violently vibrated, the heat pump device support plate 3 drives the wedge-shaped clamping block 91 to move downwards to be in contact with the stabilizing plate 93, the stabilizing plate 93 extrudes the wedge-shaped clamping block 91 to move outwards to drive the L-shaped connecting rod 101 to move towards the right side, and further drives the L-shaped rack 102 to move towards the right side, the L-shaped rack 102 drives the gear 104 to rotate, the gear 104 drives the water outlet valve 103 to rotate and close, and hot water is prevented from being continuously discharged, and the heat pump device stops working.

As shown in fig. 1, 13, 14 and 15, the heat pump device pressing mechanism 11 is further included, the heat pump device pressing mechanism 11 is used for pressing and limiting the heat pump device, the heat pump device pressing mechanism 11 includes a U-shaped pressing plate 1101, a sixth spring 1102 and a sponge pressing block 1103, the top of the cover plate 2 is slidably connected with the U-shaped pressing plate 1101, the left side and the right side of the U-shaped pressing plate 1101 are evenly connected with rubber strips at intervals, the sixth spring 1102 is connected with the bottom of the U-shaped pressing plate 1101 and the top of the cover plate 2, the sponge pressing block 1103 is bonded on the front side and the rear side of the bottom of the U-shaped pressing plate 1101, the sponge pressing block 1103 is used for pressing and limiting the heat pump device, and the sponge pressing block 1103 is in contact with the heat pump device and used for pressing and limiting the heat pump device. When resetting the apron 2, sponge briquetting 1103 and heat pump device contact, and drive U-shaped clamp plate 1101 and up-moving, sixth spring 1102 is stretched, simultaneously under the effect of sixth spring 1102, make sponge briquetting 1103 compress tightly the heat pump device all the time, thereby further fix the heat pump device, prevent that the heat pump device can shake from top to bottom and apron 2 bumps when violent vibrations, thereby damage the heat pump device, because the even interval connection in both sides has the rubber strip about U-shaped clamp plate 1101, the rubber strip can increase the frictional force between U-shaped clamp plate 1101 and the apron 2, when avoiding violent vibrations of heat pump device, U-shaped clamp plate 1101 can shake thereupon, lead to the heat pump device not hard up.

Although the present invention has been described in detail with reference to the above embodiments, it will be apparent to those skilled in the art from this disclosure that various changes or modifications can be made herein without departing from the principles and spirit of the invention as defined by the appended claims. Therefore, the detailed description of the embodiments of the present disclosure is to be construed as merely illustrative, and not limitative of the remainder of the disclosure, but rather to limit the scope of the disclosure to the full extent set forth in the appended claims.

Claims (8)

1. An ultra-low temperature air source heat pump for heating residents is characterized by comprising:

a heat pump body (1);

the upper part of the heat pump body (1) is connected with the detachable cover plate (2);

the front side and the rear side of the lower part of the heat pump body (1) are both connected with two first sliding blocks (4) in a sliding manner; the bottoms of the four first sliding blocks (4) and the inner bottom of the heat pump body (1) are connected with the first spring (5);

the heat pump device supporting plate (3) is arranged on the four first sliding blocks (4), and the heat pump device is arranged on the heat pump device supporting plate (3);

the heat pump device clamping mechanism (6) is connected between the heat pump device supporting plate (3) and the first sliding block (4) and used for limiting the heat pump device supporting plate (3), the heat pump device supporting plate (3) moves downwards to be in contact with the heat pump device clamping mechanism (6), the heat pump device clamping mechanism (6) clamps the heat pump device supporting plate (3), meanwhile, the heat pump device clamping mechanism (6) is clamped into the first sliding block (4) to limit the heat pump device supporting plate (3), and the situation that the device is damaged due to over severe vibration generated during working of the heat pump device is prevented;

the heat pump device stabilizing mechanism (7) is connected to the lower portion of the heat pump body (1) and used for clamping the heat pump device, the heat pump device stabilizing mechanism (7) moves towards the inner side to clamp the heat pump device, and the heat pump device is prevented from loosening during working.

2. The ultra-low temperature air source heat pump for heating residents as claimed in claim 1, wherein the heat pump device clamping mechanism (6) comprises:

the left side and the right side of the lower parts of the four first sliding blocks (4) are respectively connected with the arc plates (61) used for clamping the heat pump device supporting plate (3), and clamping holes are formed in the middle parts of the four first sliding blocks (4); the heat pump device supporting plate comprises clamping blocks (62), the front side and the rear side of the inner lower part of the heat pump device supporting plate (3) are connected with the two clamping blocks (62) used for limiting the heat pump device supporting plate (3) in a sliding mode, the four clamping blocks (62) are clamped with the adjacent clamping holes after sliding respectively, the heat pump device supporting plate (3) is clamped through the arc-shaped plate (61), and the clamping blocks (62) are clamped into the clamping holes to prevent the heat pump device from shaking too violently during working;

and a second spring (63) is connected between the inner sides of the four clamping blocks (62) and the heat pump device supporting plate (3).

3. The ultra-low temperature air source heat pump for heating residents as claimed in claim 2, wherein the heat pump device stabilizing mechanism (7) comprises:

the left side and the right side of the lower side in the heat pump body (1) are both connected with two second sliding blocks (71) in a sliding manner;

the clamping plate (73) is connected to the left upper side of the two second sliding blocks (71) on the left side, the clamping plate (73) used for clamping the heat pump device is connected to the right upper side of the two second sliding blocks (71) on the right side, the heat pump device is clamped by moving the clamping plate (73) towards the inner side, and the heat pump device is prevented from loosening during operation; and a third spring (72) is connected between the inner sides of the lower parts of the four second sliding blocks (71) and the heat pump body (1).

4. The ultra-low temperature air source heat pump for residential heating as claimed in claim 2, characterized by further comprising an opening mechanism (8) for pushing the block (62) out of the block hole, the opening mechanism (8) comprising: the clamping holes of the four first sliding blocks (4) are connected with concave connecting rods (83) used for pushing the clamping blocks (62) to be separated from the clamping holes in a sliding mode, and the four concave connecting rods (83) are respectively contacted with the adjacent clamping blocks (62) after moving;

the clamping device comprises a pressing rod (81), wherein the front sides of two concave connecting rods (83) on the front side are connected with the pressing rod (81), the rear sides of the two concave connecting rods (83) on the rear side are connected with the pressing rod (81), the concave connecting rods (83) are driven to extrude a clamping block (62) towards the inner side by pressing the pressing rod (81), and the pressing rod (81) is used for driving the clamping block (62) to be separated from a clamping hole;

and the fourth spring (82) is sleeved outside the four concave connecting rods (83), and two ends of the fourth spring (82) are respectively connected with the pressing rod (81) and the first sliding block (4).

5. The ultra-low temperature air source heat pump for heating residents as claimed in claim 1, further comprising a heat pump device stabilizing mechanism (9) for stabilizing the heat pump device supporting plate (3), wherein the heat pump device stabilizing mechanism (9) comprises:

the wedge-shaped clamping blocks (91) are connected with the left side and the right side inside the heat pump device supporting plate (3) in a sliding mode;

the left side and the right side of the interior of the heat pump device supporting plate (3) are sleeved with the fifth springs (92), and two ends of each fifth spring (92) are respectively connected with the wedge-shaped clamping block (91) and the heat pump device supporting plate (3); the stabilizing plate (93) is connected to the inner lower part of the heat pump body (1) in a sliding mode, the wedge-shaped clamping block (91) is driven to move downwards through the heat pump device supporting plate (3) to clamp the stabilizing plate (93), and the heat pump device is prevented from being damaged due to severe vibration;

the heat pump comprises stabilizing springs (94), wherein four stabilizing springs (94) are sleeved in the middle of a stabilizing plate (93), and two ends of each stabilizing spring (94) are respectively connected with the stabilizing plate (93) and the heat pump body (1).

6. The ultra-low temperature air source heat pump for heating residents as claimed in claim 5, further comprising a closing mechanism (10) for automatically closing the heat pump device, wherein the closing mechanism (10) comprises:

the right lower side of the right wedge-shaped clamping block (91) is connected with the L-shaped connecting rod (101);

the front side of the top of the L-shaped connecting rod (101) is connected with the L-shaped rack (102);

the water outlet valve (103) is rotationally connected with the right front side of the heat pump device;

the gear (104) is connected to the water outlet valve (103), the gear (104) is meshed with the L-shaped rack (102), the L-shaped connecting rod (101) is driven to move left and right through the wedge-shaped clamping block (91) to drive the L-shaped rack (102) to move left and right, and the L-shaped rack (102) drives the gear (104) to rotate forward and reverse to drive the water outlet valve (103) to be automatically closed and opened.

7. The ultra-low temperature air source heat pump for residential heating as claimed in claim 1, further comprising a heat pump device pressing mechanism (11) for pressing and limiting the heat pump device, wherein the heat pump device pressing mechanism (11) comprises:

the top of the cover plate (2) is connected with the U-shaped pressing plate (1101) in a sliding manner;

the bottom of the U-shaped pressing plate (1101) and the top of the cover plate (2) are connected with the sixth spring (1102); sponge briquetting (1103), both sides all bond around U-shaped clamp plate (1101) bottom and are used for compressing tightly spacing sponge briquetting (1103) to the heat pump device, sponge briquetting (1103) and heat pump device contact are used for compressing tightly spacing to the heat pump device, the power that resets through sixth spring (1102) drives U-shaped clamp plate (1101) and moves down, U-shaped clamp plate (1101) drive sponge briquetting (1103) and compress tightly the heat pump device all the time, prevent that the heat pump device from taking place violent vibrations and apron (2) and bumping.

8. The ultra-low temperature air source heat pump for heating residents as claimed in claim 7, wherein rubber strips are uniformly connected to the left and right sides of the U-shaped pressing plate (1101) at intervals, so as to increase the friction between the U-shaped pressing plate (1101) and the cover plate (2) and prevent the heat pump device from loosening when the heat pump device vibrates violently.

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