CN214960797U - Constant-temperature heat dissipation device for energy monitoring - Google Patents

Abstract

The utility model discloses an energy monitoring is with thermostatic type heat abstractor relates to energy monitoring and is with relevant technical field, including the heat conduction base, the standing groove has been seted up at heat conduction base top, the second heat conduction piece has been placed on the inside left side fixedly connected with elastically positioned mechanism of standing groove and the inside right side of standing groove, spring among the elastically positioned mechanism promotes the fly leaf and drives a plurality of I shape locating pieces and compress tightly the second heat conduction piece. The utility model discloses a be provided with heat conduction base and elastic positioning mechanism to utilize the heat conduction base to replace first heat conduction piece and second heat conduction piece among the prior art, utilize elastic positioning mechanism to carry out elastic positioning to placing in the inside second heat conduction piece of standing groove simultaneously, compare in prior art the same type device, the utility model discloses when can be comparatively convenient advance line location to the second heat conduction piece, because the heat conduction base can adopt the mode of an organic whole setting to produce, consequently still effectively reduced manufacturing cost.

Description

Constant-temperature heat dissipation device for energy monitoring

Technical Field

The utility model relates to an energy monitoring is with relevant technical field, in particular to energy monitoring is with thermostatic type heat abstractor.

Background

The energy monitoring and management system is an energy manager of an energy unit, realizes networking, informatization, digitization and visualization of monitoring and management by modern information technologies such as an intelligent terminal, a communication network, data information processing, virtual software and the like, provides various energy monitoring devices, and needs a constant-temperature heat dissipation device for energy monitoring in order to ensure the stable operation of the devices.

Patent application publication No. CN 213368463U's utility model discloses an energy monitoring is with thermostatic type heat abstractor, including radiator and fixed establishment, one side of radiator is provided with heat-conduction mechanism, and the place ahead of heat-conduction mechanism is provided with the thermometer, the outside of thermometer is provided with cooling body, and the outside of cooling body all is provided with the sealing washer, the top of sealing washer is provided with the water storage bottle, and the top of water storage bottle is provided with sealed apron, the top of sealed apron is provided with the protective cover, and the outside of protective cover is provided with the shell, the inboard of shell is provided with the third heat conduction piece. In this thermostatic type heat abstractor for energy monitoring, played the effect of transmission to the absorbed heat of first graphite piece through setting up first heat conduction piece, can be with the leading-in second heat conduction piece of heat conduction through setting up the second graphite piece, through setting up first connecting pipe and played the connection effect to cooling body, through setting up this mechanism, improved the heat-conducting effect of device.

However, the above-mentioned device still has some shortcomings when in actual use, and what is more obvious is that in order to facilitate the placement of the second graphite block, the first heat conduction block and the second heat conduction block need to be arranged in a split manner, and when the second graphite block is placed, the second graphite block needs to be coated and fixed by two sides by using the first heat conduction block and the second heat conduction block, so that the operation is inconvenient, and meanwhile, the production cost of the device is increased due to the split arrangement of the first heat conduction block and the second heat conduction block.

Therefore, it is necessary to provide a constant temperature type heat sink for energy monitoring to solve the above problems.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to provide an energy monitoring is with thermostatic type heat abstractor to solve the problem that proposes among the above-mentioned background art.

In order to achieve the above object, the utility model provides a following technical scheme: the utility model provides an energy monitoring is with thermostatic type heat abstractor, includes the heat conduction base, the standing groove has been seted up at heat conduction base top, the second heat conduction piece has been placed on the inside left side fixedly connected with elastically positioned mechanism of standing groove and the inside right side of standing groove, spring among the elastically positioned mechanism promotes the fly leaf and drives a plurality of I shape locating pieces and compress tightly the second heat conduction piece.

Preferably, the elastic positioning mechanism comprises a movable plate, a spring and an I-shaped positioning block.

Preferably, the movable plate is arranged on the inner side of the placing groove in a sliding mode, the springs are arranged in two, the springs are fixedly connected to two ends of the left side of the movable plate respectively, the left ends of the springs are fixedly connected with the inner wall of the placing groove, the I-shaped positioning blocks are arranged in a plurality of, and the I-shaped positioning blocks are evenly and fixedly arranged on the right side of the movable plate.

Preferably, the right side of the heat conduction base is fixedly provided with an installation cover, and a first heat conduction block is placed on the inner side of the installation cover.

Preferably, the right side of the front surface and the right side of the back surface of the heat conduction base are both provided with a fixture block, and the fixture blocks are fixedly connected with the heat conduction base.

Preferably, threaded holes are formed in the left side of the front face and the left side of the back face of the heat conduction base, and connecting pipes are connected to the inner side of the threaded holes in a threaded mode.

The utility model discloses a technological effect and advantage:

the utility model discloses a be provided with heat conduction base and elastic positioning mechanism to utilize the heat conduction base to replace first heat conduction piece and second heat conduction piece among the prior art, utilize elastic positioning mechanism to carry out elastic positioning to placing in the inside second heat conduction piece of standing groove simultaneously, compare in prior art the same type device, the utility model discloses when can be comparatively convenient advance line location to the second heat conduction piece, because the heat conduction base can adopt the mode of an organic whole setting to produce, consequently still effectively reduced manufacturing cost.

Drawings

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

Fig. 2 is a schematic view of the overlooking structure of the heat-conducting base of the present invention.

Fig. 3 is a schematic view of the three-dimensional structure of the movable plate and the i-shaped positioning block of the present invention.

In the figure: 1. a thermally conductive base; 2. a placement groove; 3. an elastic positioning mechanism; 31. a movable plate; 32. a spring; 33. an I-shaped positioning block; 4. a second heat-conducting block; 5. mounting a cover; 6. a first heat-conducting block; 7. a clamping block; 8. and (4) connecting the pipes.

Detailed Description

The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative work belong to the protection scope of the present invention.

The utility model provides a constant temperature type heat abstractor for energy monitoring as shown in fig. 1-3, including heat conduction base 1, standing groove 2 has been seted up at heat conduction base 1 top, second heat conduction piece 4 has been placed on the inside left side fixedly connected with elastically positioned mechanism 3 of standing groove 2 and the inside right side of standing groove 2, spring 32 among the elastically positioned mechanism 3 promotes fly leaf 31 and drives a plurality of I shape locating pieces 33 and compress tightly second heat conduction piece 4.

As shown in fig. 2 and 3, the elastic positioning mechanism 3 includes a movable plate 31, a spring 32, and an i-shaped positioning block 33.

More specifically, the movable plate 31 is slidably disposed inside the placing groove 2, two springs 32 are disposed, two springs 32 are respectively fixedly connected to two ends of the left side of the movable plate 31, the left ends of the two springs 32 are fixedly connected to the inner wall of the placing groove 2, a plurality of i-shaped positioning blocks 33 are disposed, the plurality of i-shaped positioning blocks 33 are uniformly and fixedly disposed on the right side of the movable plate 31, so that a technician can take the second heat conduction block 4, and press the left end of the second heat conduction block 4 against the right side surfaces of the plurality of i-shaped positioning blocks 33, push the second heat conduction block 4 to the left side, compress the springs 32 through the i-shaped positioning blocks 33 and the movable plate 31 by the second heat conduction block 4, then press the second heat conduction block 4 downward, so that the second heat conduction block 4 completely enters the placing groove 2, at this time, under the elastic force of the springs 32, the spring 32 pushes the plurality of i-shaped positioning blocks 33 through the movable plate 31, so that the i-shaped positioning blocks 33 are matched with the inside of the placing groove 2 to compress the second heat-conducting block 4.

As shown in fig. 1 and 2, a mounting cover 5 is fixedly arranged on the right side of the heat conduction base 1, a first heat conduction block 6 is placed on the inner side of the mounting cover 5, fixture blocks 7 are arranged on the right side of the front surface and the right side of the back surface of the heat conduction base 1, and the fixture blocks 7 are fixedly connected with the heat conduction base 1.

Simultaneously, threaded holes are formed in the left side of the front face and the left side of the back face of the heat conduction base 1, and a connecting pipe 8 is connected to the inner side of each threaded hole in a threaded manner.

The utility model discloses the theory of operation:

in practical use, at the moment, the device is in a state shown in fig. 2, when the second heat conduction block 4 and the first heat conduction block 6 need to be placed, a technician can firstly take the first heat conduction block 6, and then insert the first heat conduction block 6 into the mounting cover 5 from the opening at the top of the mounting cover 5;

then take second heat conduction piece 4 again to make 4 left ends of second heat conduction piece support and press in the right flank of a plurality of I shape locating pieces 33, promote second heat conduction piece 4 to the left side this moment, make second heat conduction piece 4 compress spring 32 through I shape locating piece 33 and fly leaf 31, then press second heat conduction piece 4 downwards, make second heat conduction piece 4 enter into standing groove 2 inside completely, at this moment under the spring action of spring 32, spring 32 promotes a plurality of I shape locating pieces 33 through fly leaf 31, and then make I shape locating piece 33 cooperate the standing groove 2 inside to compress tightly second heat conduction piece 4, the operation finishes.

Finally, it should be noted that: although the present invention has been described in detail with reference to the foregoing embodiments, it will be apparent to those skilled in the art that modifications and variations can be made in the embodiments or in part of the technical features of the embodiments without departing from the spirit and the scope of the invention.

Claims (6)

1. The utility model provides an energy monitoring is with thermostatic type heat abstractor which characterized in that: including heat conduction base (1), standing groove (2) have been seted up at heat conduction base (1) top, second heat conduction piece (4) have been placed on inside left side fixedly connected with elastic positioning mechanism (3) of standing groove (2) and the inside right side of standing groove (2), spring (32) among elastic positioning mechanism (3) promote fly leaf (31) and drive a plurality of I shape locating pieces (33) and compress tightly second heat conduction piece (4).

2. The constant-temperature heat dissipation device for energy monitoring as recited in claim 1, wherein: the elastic positioning mechanism (3) comprises a movable plate (31), a spring (32) and an I-shaped positioning block (33).

3. The constant-temperature heat dissipation device for energy monitoring as recited in claim 2, wherein: the movable plate (31) is arranged on the inner side of the placing groove (2) in a sliding mode, the number of the springs (32) is two, the springs (32) are fixedly connected to the two ends of the left side of the movable plate (31) respectively, the left ends of the springs (32) are fixedly connected with the inner wall of the placing groove (2), the I-shaped positioning blocks (33) are arranged in a plurality of, and the I-shaped positioning blocks (33) are evenly and fixedly arranged on the right side of the movable plate (31).

4. The constant-temperature heat dissipation device for energy monitoring as recited in claim 3, wherein: the heat conduction base (1) right side is fixed and is provided with an installation cover (5), and a first heat conduction block (6) is placed on the inner side of the installation cover (5).

5. The constant-temperature heat dissipation device for energy monitoring as recited in claim 4, wherein: the heat conduction base is characterized in that clamping blocks (7) are arranged on the right side of the front face and the right side of the back face of the heat conduction base (1), and the clamping blocks (7) are fixedly connected with the heat conduction base (1).

6. The constant-temperature heat dissipation device for energy monitoring as recited in claim 5, wherein: threaded holes are formed in the left side of the front face and the left side of the back face of the heat conduction base (1), and a connecting pipe (8) is connected to the inner side of each threaded hole in a threaded mode.

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