CN211782036U - Heat exchange device of solar heat pump - Google Patents

Abstract

The utility model discloses a heat transfer device of solar heat pump, including the heat-preserving container, this some water storage buckets of installing of inside of heat-preserving container, the bottom fixed mounting of heat-preserving container has the support frame, one side of heat-preserving container is provided with the vacuum heat exchange tube, the jack has been seted up to one side that the heat-preserving container is close to the vacuum heat exchange tube, the inside of locating the jack is inserted on the top of vacuum heat exchange tube to communicate with the water storage bucket, just vacuum heat exchange tube and jack sliding connection, the support frame is close to the top fixed mounting end extension board of vacuum heat exchange tube one side. The utility model discloses a rotate corresponding fastening bolt, drive the support sleeve decline, make the support sleeve break away from with vacuum heat exchange tube gradually to carry out indirect support to vacuum heat exchange tube through plastic sleeve, go up plastic sleeve, and slowly pull the vacuum heat exchange tube downwards and can take out vacuum heat exchange tube, improved the convenience of heat transfer device installation, dismantlement widely.

Description

Heat exchange device of solar heat pump

Technical Field

The utility model relates to a new forms of energy equipment technical field, concretely relates to heat transfer device of solar heat pump.

Background

The solar heat pump is a device for absorbing solar energy, extracting heat from air, combining the solar energy with air energy and converting the heat, and the solar water heater is a common form of the solar heat pump and adopts the principle that a reflector is used for gathering the heat in a vacuum heat exchange tube for absorption, and the principle that hot water in the heat exchange tube floats and sinks cold water is utilized to enable the water to generate microcirculation so as to obtain required hot water;

the prior art has the following defects: the supporting device of the existing vacuum heat exchange tube is simple in structure and easy to install, when a certain vacuum heat exchange tube needs to be disassembled, other vacuum heat exchange tubes need to be disassembled in advance, the vacuum heat exchange tube needs to be manually contacted for removal during disassembly, the vacuum heat exchange tube is easy to support and damage due to overlarge stress, and the disassembly process is very inconvenient.

SUMMERY OF THE UTILITY MODEL

The utility model aims at providing a heat transfer device of solar heat pump through rotating corresponding fastening bolt, drives the support sleeve decline, makes the support sleeve break away from with vacuum heat exchange tube gradually to carry out indirect support to vacuum heat exchange tube through plastic sleeve, at last, go up plastic sleeve, and slowly draw the vacuum heat exchange tube downwards and can take out vacuum heat exchange tube, in order to solve the above-mentioned weak point in the technique.

In order to achieve the above object, the present invention provides the following technical solutions: a heat exchange device of a solar heat pump comprises a heat-insulating barrel, a water storage barrel is arranged in the heat-insulating barrel, a support frame is fixedly arranged at the bottom of the heat-insulating barrel, a vacuum heat exchange tube is arranged on one side of the heat-insulating barrel, a jack is arranged on one side of the heat-insulating barrel close to the vacuum heat exchange tube, the top end of the vacuum heat exchange tube is inserted into the jack and communicated with the water storage barrel, the vacuum heat exchange tube is connected with the jack in a sliding manner, a bottom support plate is fixedly arranged at the top of one side of the support frame close to the vacuum heat exchange tube, a sliding hole is arranged in the bottom support plate, a support sleeve is arranged in the sliding hole and connected with the sliding hole in a sliding manner, the bottom end of the vacuum heat exchange tube is inserted into the support sleeve, a bottom support plate is arranged at the bottom of, the top of end fagging is rotated and is connected with connecting bolt, connecting bolt's top runs through the curb plate to with curb plate threaded connection, the inside of end fagging is provided with fastening bolt, fastening bolt and end fagging threaded connection, fastening bolt's top is rotated with the bottom of support sleeve and is connected, the bottom of vacuum heat exchange tube is provided with the plastic sleeve, the outside of vacuum heat exchange tube is located to the plastic sleeve sliding sleeve, just the telescopic bottom sliding connection of plastics is in the inside of support sleeve.

Preferably, a rubber layer is arranged on one side, close to the bottom end of the vacuum heat exchange tube, of the inner cavity of the supporting sleeve, and the rubber layer is adhered inside the supporting sleeve.

Preferably, the number of the connecting bolts is four, and the four connecting bolts are respectively positioned at four top corners of the bottom supporting plate.

Preferably, one end of the connecting bolt close to the bottom supporting plate is fixedly provided with two convex rings, and the two convex rings are respectively positioned at two sides of the bottom supporting plate.

Preferably, one side of the water storage barrel close to the vacuum heat exchange tube is provided with an insertion tube, the top end of the vacuum heat exchange tube is inserted into the insertion tube and is connected with the insertion tube in a sliding mode, an inner contraction section is arranged at one end, close to the heat preservation barrel, of the inside of the insertion tube, and a sealing ring is installed between the top end of the vacuum heat exchange tube and the inner contraction section of the inside of the insertion tube.

Preferably, four apex angle departments of support frame bottom all are provided with the mounting panel, the mounting hole has all been seted up to four apex angle departments of mounting panel.

Preferably, the mounting plate is rotatably connected with the support frame through a hinge.

In the technical scheme, the utility model provides a technological effect and advantage:

the utility model has the advantages that the supporting sleeve is connected in the bottom support plate in a sliding way, when a certain vacuum heat exchange tube needs to be disassembled, the supporting sleeve can be driven to descend by rotating the corresponding fastening bolt, the supporting sleeve is gradually separated from the vacuum heat exchange tube, and the vacuum heat exchange tube is indirectly supported by the plastic sleeve, so that the safety of the heat exchange device during disassembly is improved, finally, the plastic sleeve slides upwards, the vacuum heat exchange tube can be taken out by slowly downwards pulling the vacuum heat exchange tube, when the vacuum heat exchange tube needs to be disassembled simultaneously, the bottom support plate can be downwards moved by rotating the four connecting bolts, all the supporting sleeves can be driven to downwards move, and then the vacuum heat exchange tubes can be taken down one by one, so that the heat exchange device is more convenient to install and disassemble, compared with the prior art, the convenience of the installation and disassembly of the heat exchange device is greatly, the practicability of the heat exchange device is enhanced.

Drawings

In order to more clearly illustrate the embodiments of the present application or the technical solutions in the prior art, the drawings needed to be used in the embodiments will be briefly described below, and it is obvious that the drawings in the following description are only some embodiments described in the present invention, and other drawings can be obtained by those skilled in the art according to these drawings.

Fig. 1 is a schematic view of the overall structure of the present invention.

Fig. 2 is an enlarged view of a part of the structure of the present invention.

Fig. 3 is a longitudinal sectional view of the partial structure of the present invention.

Fig. 4 is an enlarged view of the structure of the portion a of fig. 1 according to the present invention.

Fig. 5 is a schematic view of the overall structure of the bottom supporting plate of the present invention.

Description of reference numerals:

1. a heat-preserving barrel; 2. a support frame; 3. a vacuum heat exchange tube; 4. a bottom support plate; 5. a support sleeve; 6. a bottom supporting plate; 7. a plastic sleeve; 8. mounting a plate; 9. a side plate; 10. a connecting bolt; 11. fastening a bolt; 12. a convex ring; 13. a slide hole; 14. a rubber layer; 15. a water storage barrel; 16. a jack; 17. inserting a tube; 18. and (5) sealing rings.

Detailed Description

In order to make the technical solution of the present invention better understood by those skilled in the art, the present invention will be further described in detail with reference to the accompanying drawings.

The utility model provides a heat exchange device of a solar heat pump as shown in figures 1-5, which comprises a heat preservation barrel 1, a water storage barrel 15 is arranged in the heat preservation barrel 1, a support frame 2 is fixedly arranged at the bottom of the heat preservation barrel 1, a vacuum heat exchange tube 3 is arranged at one side of the heat preservation barrel 1, a jack 16 is arranged at one side of the heat preservation barrel 1 close to the vacuum heat exchange tube 3, the top end of the vacuum heat exchange tube 3 is inserted in the jack 16 and communicated with the water storage barrel 15, the vacuum heat exchange tube 3 is connected with the jack 16 in a sliding way, a bottom support plate 4 is fixedly arranged at the top of the support frame 2 close to one side of the vacuum heat exchange tube 3, a sliding hole 13 is arranged in the bottom support plate 4, a support sleeve 5 is arranged in the sliding hole 13, the support sleeve 5 is connected with the sliding hole 13 in a sliding way, the bottom end of the vacuum heat exchange, a bottom supporting plate 6 is arranged at the bottom of the bottom supporting plate 4, side plates 9 are fixedly connected to both ends of the bottom supporting plate 4, a connecting bolt 10 is rotatably connected to the top of the bottom supporting plate 6, the top end of the connecting bolt 10 penetrates through the side plates 9 and is in threaded connection with the side plates 9, a fastening bolt 11 is arranged inside the bottom supporting plate 6, the fastening bolt 11 is in threaded connection with the bottom supporting plate 6, the top end of the fastening bolt 11 is rotatably connected with the bottom of a supporting sleeve 5, a plastic sleeve 7 is arranged at the bottom end of the vacuum heat exchange tube 3, the plastic sleeve 7 is slidably sleeved outside the vacuum heat exchange tube 3, and the bottom end of the plastic sleeve 7 is slidably connected inside the supporting sleeve 5;

further, in the above technical scheme, a rubber layer 14 is arranged on one side of the inner cavity of the support sleeve 5 close to the bottom end of the vacuum heat exchange tube 3, and the rubber layer 14 is adhered inside the support sleeve 5, so as to fully protect the installation of the vacuum heat exchange tube 3;

further, in the above technical solution, the number of the connecting bolts 10 is four, and the four connecting bolts 10 are respectively located at four top corners of the bottom bracing plate 6, so as to enhance the connecting strength of the bottom bracing plate 6;

further, in the above technical solution, two convex rings 12 are fixedly installed at one end of the connecting bolt 10 close to the bottom supporting plate 6, and the two convex rings 12 are respectively located at two sides of the bottom supporting plate 6, so as to support the rotation between the connecting bolt 10 and the bottom supporting plate 6;

further, in the above technical scheme, an insertion tube 17 is arranged on one side of the water storage barrel 15 close to the vacuum heat exchange tube 3, the top end of the vacuum heat exchange tube 3 is inserted into the insertion tube 17 and is slidably connected with the insertion tube 17, an inner contraction section is arranged at one end of the inner part of the insertion tube 17 close to the heat preservation barrel 1, a sealing ring 18 is arranged between the top end of the vacuum heat exchange tube 3 and the inner contraction section of the inner part of the insertion tube 17, and when the support sleeve 5 is adjusted to be pushed upwards, the vacuum heat exchange tube 3 can be driven to be tightly attached to the sealing ring 18, so that the sealing performance of the device is;

further, in the above technical scheme, mounting plates 8 are arranged at four top corners of the bottom of the support frame 2, and mounting holes are formed in the four top corners of the mounting plates 8 so that the device can be connected with an existing bolt assembly through the mounting plates 8, so that the device is more firmly mounted, and the mounting plates 8 can be used for pre-embedding and pressing;

further, in the above technical solution, the mounting plate 8 is rotatably connected with the support frame 2 through a hinge, so that the mounting surface can be better adapted to when mounting by using the rotation of the mounting plate 8;

the implementation mode is specifically as follows: in actual installation, the top ends of the vacuum heat exchange tubes 3 are inserted into the insertion tubes 17 through the insertion holes 16 and are communicated with the water storage barrel 15, the bottom support plate 4 is arranged at one end of the support frame 2, the support sleeve 5 is connected to the inside of the bottom support plate 4 in a sliding manner, after the bottom support plate 6 is installed, the support sleeve 5 is pushed upwards by rotating the fastening bolt 11 inside the bottom support plate 6 and connecting the fastening bolt 11 with the bottom support plate 6 through threads, so that the bottom ends of the vacuum heat exchange tubes 3 are clamped into the inside of the support sleeve 5 to realize fixation, meanwhile, the vacuum heat exchange tubes 3 are driven to be tightly attached to the sealing rings 18 to improve the sealing performance of the device, when one vacuum heat exchange tube 3 needs to be disassembled, the corresponding fastening bolt 11 can be rotated reversely to drive the support sleeve 5 to descend, and as the top of the vacuum heat exchange tube 3 is tightly connected with the water storage barrel 15, the supporting sleeve 5 can be gradually separated from the vacuum heat exchange tube 3, the plastic sleeve 7 is sleeved at the bottom end of the vacuum heat exchange tube 3, and the bottom end of the plastic sleeve 7 is connected into the supporting sleeve 5 in a sliding manner, so that when the supporting sleeve 5 descends and is separated from the vacuum heat exchange tube 3, the plastic sleeve 7 can also slide downwards along with the supporting sleeve 5, but the plastic sleeve 7 cannot be separated from the vacuum heat exchange tube 3, therefore, the plastic sleeve 7 can indirectly support the vacuum heat exchange tube 3, the safety of the heat exchange device during disassembly is improved, finally, the plastic sleeve 7 slides upwards, the vacuum heat exchange tube 3 can be taken out by slowly pulling the vacuum heat exchange tube 3 downwards, when the vacuum heat exchange tube 3 is required to be disassembled simultaneously, the bottom supporting plate 6 can be moved downwards by rotating the four connecting bolts 10, all the supporting sleeves 5 can be driven to move downwards, and then the vacuum heat exchange tubes 3 can be taken down one, thereby make heat transfer device's installation dismantle more convenient, this embodiment has specifically solved the problem that is not convenient for install and dismantle vacuum heat exchange tube 3 among the prior art.

This practical theory of operation: through rotating corresponding fastening bolt 11, drive support sleeve 5 and descend, make support sleeve 5 break away from with vacuum heat exchange tube 3 gradually, and carry out indirect support to vacuum heat exchange tube 3 through plastic sleeve 7, at last, go up plastic sleeve 7, and slowly draw the vacuum heat exchange tube 3 of downwards twitching can take out vacuum heat exchange tube 3, and when needing to pull down simultaneously using vacuum heat exchange tube 3, can make bottom sprag board 6 move down through rotating four connecting bolt 10, can drive all support sleeves 5 and move down, and take off vacuum heat exchange tube 3 one by one.

While certain exemplary embodiments of the present invention have been described above by way of illustration only, it will be apparent to those of ordinary skill in the art that the described embodiments may be modified in various different ways without departing from the spirit and scope of the present invention. Accordingly, the drawings and description are illustrative in nature and should not be construed as limiting the scope of the invention.

Claims (7)

1. The utility model provides a heat transfer device of solar thermal energy pump, includes heat-preserving container (1), its characterized in that: a water storage barrel (15) is installed inside the heat-insulating barrel (1), a support frame (2) is fixedly installed at the bottom of the heat-insulating barrel (1), a vacuum heat exchange tube (3) is arranged on one side of the heat-insulating barrel (1), a jack (16) is formed in one side, close to the vacuum heat exchange tube (3), of the heat-insulating barrel (1), the top end of the vacuum heat exchange tube (3) is inserted into the jack (16) and communicated with the water storage barrel (15), the vacuum heat exchange tube (3) is in sliding connection with the jack (16), a bottom support plate (4) is fixedly installed at the top of one side, close to the vacuum heat exchange tube (3), of the support frame (2), a sliding hole (13) is formed in the bottom support plate (4), a support sleeve (5) is arranged inside the sliding hole (13), the support sleeve (5) is in sliding connection with the sliding hole (13), and the bottom end of the vacuum heat exchange tube (3) is inserted into the, the bottom of the bottom support plate (4) is provided with a bottom support plate (6), two ends of the bottom support plate (4) are fixedly connected with side plates (9), the top of the bottom support plate (6) is rotatably connected with connecting bolts (10), the top ends of the connecting bolts (10) penetrate through the side plates (9) and are in threaded connection with the side plates (9), fastening bolts (11) are arranged inside the bottom support plate (6), the fastening bolts (11) are in threaded connection with the bottom support plate (6), the top ends of the fastening bolts (11) are rotatably connected with the bottom of the support sleeve (5), the bottom end of the vacuum heat exchange tube (3) is provided with a plastic sleeve (7), the plastic sleeve (7) is slidably sleeved outside the vacuum heat exchange tube (3), and the bottom end of the plastic sleeve (7) is slidably connected inside the support sleeve (5).

2. A heat exchange unit for a solar thermal pump according to claim 1, characterized in that: one side of the inner cavity of the supporting sleeve (5) close to the bottom end of the vacuum heat exchange tube (3) is provided with a rubber layer (14), and the rubber layer (14) is adhered inside the supporting sleeve (5).

3. A heat exchange unit for a solar thermal pump according to claim 1, characterized in that: the number of the connecting bolts (10) is four, and the connecting bolts (10) are respectively positioned at four top corners of the bottom supporting plate (6).

4. A heat exchange unit for a solar thermal pump according to claim 1, characterized in that: one end of the connecting bolt (10) close to the bottom supporting plate (6) is fixedly provided with two convex rings (12), and the two convex rings (12) are respectively positioned at two sides of the bottom supporting plate (6).

5. A heat exchange unit for a solar thermal pump according to claim 1, characterized in that: one side that water storage bucket (15) are close to vacuum heat exchange tube (3) is provided with intubate (17), the inside of locating intubate (17) is inserted on the top of vacuum heat exchange tube (3) to with intubate (17) sliding connection, just the one end that intubate (17) inside is close to heat-preserving container (1) is provided with the section of contracting in, install sealing washer (18) between the top of vacuum heat exchange tube (3) and the inside section of contracting of intubate (17).

6. A heat exchange unit for a solar thermal pump according to claim 1, characterized in that: four apex angle departments of support frame (2) bottom all are provided with mounting panel (8), the mounting hole has all been seted up to four apex angle departments of mounting panel (8).

7. The heat exchange device of a solar thermal pump according to claim 6, characterized in that: the mounting plate (8) is rotatably connected with the support frame (2) through a hinge.

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