CN218627882U - Micro-tube array type efficient heat exchanger - Google Patents

Abstract

The utility model discloses a high-efficient heat exchanger of microtubule array, dust cover including heat transfer case and its top fixed connection, be provided with extrusion room and heat dissipation room in the heat transfer case, the heat dissipation room includes fixed connection's on the heat transfer incasement wall mounting panel, the intercommunication has a plurality of connecting pipes in the mounting panel, the utility model relates to a heat exchanger technical field. This microtubule array high efficiency heat exchanger, through set up extrusion device in the heat transfer case, make the coolant liquid pushed into in the drainage tube by extrusion device, flow into the heat dissipation through the drainage tube in, flow into logical groove and get back to in the extrusion chamber from the heat dissipation indoor, reach the effect that recycles the coolant liquid and dispel the heat to the heat dissipation chamber, and the coolant liquid when flowing into the heat dissipation indoor, the air exchanger can exchange outside cold air and the indoor air of heat dissipation, make the indoor temperature of heat dissipation can discharge, and realize high-efficient heat dissipation and the extravagant effect of coolant liquid reduction through coolant liquid circulative cooling.

Description

Micro-tube array type efficient heat exchanger

Technical Field

The utility model relates to a heat exchanger technical field specifically is a high-efficient heat exchanger of microtubule array.

Background

The existing heat exchangers generally use a heat dissipation method, and most of the heat exchangers use cold water and hot water to carry out cold-heat exchange for cooling, so that the cooling efficiency is low.

SUMMERY OF THE UTILITY MODEL

Not enough to prior art, the utility model provides a high-efficient heat exchanger of microtubule array has solved the not high problem of radiating efficiency.

In order to achieve the above purpose, the utility model discloses a following technical scheme realizes: the utility model provides a microtubule array high-efficient heat exchanger, includes heat transfer case and its top fixed connection's dust cover, be provided with squeezing chamber and radiating chamber in the heat transfer case, the radiating chamber includes fixed connection's on the heat transfer incasement wall mounting panel, the intercommunication has a plurality of connecting pipes in the mounting panel, the one end of connecting pipe extends mounting panel and connecting pipe sliding connection has the heating panel, fixedly connected with limiting plate one on the heat transfer bottom of the case portion inner wall, a plurality of through-holes have been seted up on a limiting plate surface.

Preferably, a through groove is formed in the first limiting plate, the water outlet of the through hole is in surface contact with the through groove, a water outlet at one end of the through groove is communicated with a water outlet, and one end of the water outlet extends into the extrusion chamber.

Preferably, the drainage blanket has been seted up at the top of mounting panel, sliding connection has the heat dissipation microtubule in the heating panel, the surface contact of heat dissipation microtubule has miniature heating panel, the adaptation mouth has been seted up on the surface of miniature heating panel, a plurality of thermovents have been seted up around the adaptation mouth, the bottom fixedly connected with limiting plate two of miniature heating panel.

Preferably, the extrusion chamber includes the axis of rotation of being connected with heat transfer case top inner wall rotation, the top fixedly connected with ventilator of axis of rotation, the bottom fixedly connected with connecting axle of axis of rotation, the dysmorphism groove has been seted up on the surface of connecting axle, fixedly connected with division board on the inner wall of heat transfer case bottom, the top of division board and the bottom fixed connection of mounting panel.

Preferably, the inner wall of the left side of the heat exchange box and the surface of the right side of the partition plate are fixedly connected with drainage tubes, one end of each drainage tube is fixedly connected with a diagonal flow plate, the drainage tubes are communicated with the diagonal flow plates, water outlets of the drainage tubes are communicated with a water outlet nozzle, one side of one drainage tube is fixedly connected with a fixing block, and an adaptive groove is formed in the fixing block.

Preferably, sliding connection has 7 style of calligraphy slide bars in the adaptation groove, the one end of 7 style of calligraphy slide bars extend the adaptation groove and with the inner wall sliding connection in dysmorphism groove, the other end fixedly connected with connective bar of 7 style of calligraphy slide bars, two the opposite side fixedly connected with stripper plate of connective bar, one side fixedly connected with slider of another drainage tube, set up the spout in the slider, the internal surface of spout and the surface sliding connection of one of them connective bar.

Advantageous effects

The utility model provides a microtubule array high efficiency heat exchanger. Compared with the prior art, the method has the following beneficial effects:

(1) This microtubule array high-efficient heat exchanger, through set up extrusion device in the heat transfer case, make the coolant liquid pushed into in the drainage tube by extrusion device, flow into the heat dissipation chamber through the drainage tube, flow into logical groove and get back to in the extrusion chamber from the heat dissipation chamber, circulative cooling, and the coolant liquid is when flowing into the heat dissipation chamber, the chance of taking a breath exchanges outside cold air and the indoor air of heat dissipation, make the temperature in the heat dissipation chamber can discharge, and through setting up miniature heating panel on heat dissipation microtubule surface, and a plurality of thermovents have been seted up on the surface of miniature heating panel, make miniature heating panel can conduct the temperature to the heating panel surface better, and realize high-efficient heat dissipation and reduce the waste of coolant liquid through coolant liquid circulative cooling.

Drawings

FIG. 1 is a front view of the internal structure of the present invention;

fig. 2 is a front view of a first partial structure of the present invention;

FIG. 3 is a front view of a second partial structure of the present invention;

FIG. 4 is an enlarged view of a portion of the structure of the present invention;

fig. 5 is a perspective view of the present invention.

In the figure: 1-heat exchange box, 2-extrusion chamber, 3-heat dissipation chamber, 4-dust cover, 21-rotating shaft, 22-ventilator, 23-connecting shaft, 24-special-shaped groove, 25-separating plate, 26-drainage tube, 27-oblique flow plate, 28-water outlet nozzle, 29-fixed block, 291-adapting groove, 292-7-shaped sliding rod, 293-connecting rod, 294-extrusion plate, 295-sliding block, 31-mounting plate, 32-connecting pipe, 33-heat dissipation plate, 34-limiting plate I, 35-through groove, 36-water outlet, 37-water drainage layer, 38-heat dissipation micro-pipe, 39-adapting port, 391-limiting plate II and 392-micro heat dissipation plate.

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.

Referring to fig. 1-5, the present invention provides two technical solutions; the method specifically comprises the following embodiments:

example one

A microtubule array type high efficiency heat exchanger comprises a heat exchange box 1 and a dust cover 4 fixedly connected with the top of the heat exchange box 1, wherein the dust cover 4 has larger sundries or dust falling into the heat exchange box 1, a squeezing chamber 2 and a heat dissipation chamber 3 are arranged in the heat exchange box 1, the heat dissipation chamber 3 comprises a mounting plate 31 fixedly connected with the inner wall of the heat exchange box 1, one end of the mounting plate 31 is fixedly connected with an oblique flow plate 27, a plurality of connecting pipes 32 are communicated in the mounting plate 31, the water inlets of the connecting pipes 32 are exposed out of the surface of the mounting plate 31, clamping parts are arranged in the connecting pipes 32 to limit a heat dissipation plate 33, one end of the connecting pipe 32 extends out of the mounting plate 31 and is slidably connected with the heat dissipation plate 33 in the connecting pipe 32, a first limiting plate 34 is fixedly connected with the inner wall at the bottom of the heat exchange box 1, the first limiting plate 34 can limit the heat dissipation plate 33, a plurality of through holes are arranged on the surface of the first limiting plate 34, a through groove 35 is arranged in the first limiting plate 34, the through groove 35 can discharge the cooling liquid into the extrusion chamber 2, a water outlet of the through hole is in contact with the surface of the through groove 35, a water outlet 36 is communicated with a water outlet at one end of the through groove 35, the water outlet 36 can increase the water discharge efficiency of the through groove 35, one end of the water outlet 36 extends into the extrusion chamber 2, a water discharge layer 37 is arranged at the top of the mounting plate 31, the water discharge layer 37 can enable the cooling liquid to enter the heat dissipation chamber 3 and enable the ventilator 22 to exchange air in the heat dissipation chamber 3 with outside air, the heat dissipation micro-tube 38 is connected in the heat dissipation plate 33 in a sliding mode, the outer surface of the heat dissipation micro-tube 38 is in contact with the micro heat dissipation plate 392, the micro heat dissipation plate 392 can transfer heat of the heat dissipation micro-tube 38 to the surface of the heat dissipation plate 33, an adaptation hole 39 is arranged on the surface of the micro heat dissipation plate 392, the size of the adaptation hole 39 is adapted to the size of the heat dissipation micro-tube 38, and a plurality of heat dissipation holes are arranged around the adaptation hole 39, the bottom of the micro heat dissipation plate 392 is fixedly connected with a second limiting plate 391, and the second limiting plate 391 can limit the heat dissipation micro-tube 38.

In this embodiment, the compressing chamber 2 includes a rotating shaft 21 rotatably connected to the inner wall of the top of the heat exchange box 1, the top of the rotating shaft 21 is fixedly connected to a ventilator 22, the ventilator 22 is electrically connected to an external power source, and the bottom of the ventilator 22 is provided with a connecting rod, when the ventilator 22 rotates, the connecting rod drives the rotating shaft 21 to rotate, the bottom of the rotating shaft 21 is fixedly connected to a connecting shaft 23, the surface of the connecting shaft 23 is provided with a special-shaped groove 24, the inner wall of the bottom of the heat exchange box 1 is fixedly connected to a partition plate 25, the partition plate 25 separates the compressing chamber 2 from the heat dissipation chamber 3, the top of the partition plate 25 is fixedly connected to the bottom of the mounting plate 31, the inner wall of the left side of the heat exchange box 1 and the surface of the right side of the partition plate 25 are both fixedly connected to a drainage tube 26, the drainage tube 26 can drain the cooling liquid into the drainage layer 37, one end of the drainage tube 26 is fixedly connected to an inclined flow plate 27, the inclined flow plate 27 has an angle such that the cooling liquid can flow more quickly flow into the mounting plate 31 when flowing into the inclined flow plate 27, the drainage tube 26 is communicated with a water outlet, one side of the drainage tube 26 is fixedly connected to a fixed block 29, an adaptive groove 291 is fixedly connected to a slide bar 293, and a slide bar 292 is connected to the slide bar 293, and a slide bar 293 is connected to the slide bar 295 connected to the other side of the slide bar 295, and a slide bar 293, and connected to the slide bar 293, and a slide bar 295 is connected to the slide bar 293, and a slide bar connector 295 is connected to the slide connector 295.

Example two

A microtubule array type high efficiency heat exchanger comprises a heat exchange box 1 and a dust cover 4 fixedly connected with the top of the heat exchange box 1, wherein the dust cover 4 has larger sundries or dust falling into the heat exchange box 1, a squeezing chamber 2 and a heat dissipation chamber 3 are arranged in the heat exchange box 1, the heat dissipation chamber 3 comprises a mounting plate 31 fixedly connected with the inner wall of the heat exchange box 1, one end of the mounting plate 31 is fixedly connected with an oblique flow plate 27, a plurality of connecting pipes 32 are communicated in the mounting plate 31, the water inlets of the connecting pipes 32 are exposed out of the surface of the mounting plate 31, clamping parts are arranged in the connecting pipes 32 to limit a heat dissipation plate 33, one end of the connecting pipe 32 extends out of the mounting plate 31 and is slidably connected with the heat dissipation plate 33 in the connecting pipe 32, a first limiting plate 34 is fixedly connected with the inner wall at the bottom of the heat exchange box 1, the first limiting plate 34 can limit the heat dissipation plate 33, a plurality of through holes are arranged on the surface of the first limiting plate 34, a through groove 35 is arranged in the first limiting plate 34, the through groove 35 can discharge the cooling liquid into the extrusion chamber 2, a water outlet of the through hole is in contact with the surface of the through groove 35, a water outlet 36 is communicated with a water outlet at one end of the through groove 35, the water outlet 36 can increase the water discharge efficiency of the through groove 35, one end of the water outlet 36 extends into the extrusion chamber 2, a water discharge layer 37 is arranged at the top of the mounting plate 31, the water discharge layer 37 can enable the cooling liquid to enter the heat dissipation chamber 3 and enable the ventilator 22 to exchange air in the heat dissipation chamber 3 with outside air, the heat dissipation micro-tube 38 is connected in the heat dissipation plate 33 in a sliding mode, the outer surface of the heat dissipation micro-tube 38 is in contact with the micro heat dissipation plate 392, the micro heat dissipation plate 392 can transfer heat of the heat dissipation micro-tube 38 to the surface of the heat dissipation plate 33, an adaptation hole 39 is arranged on the surface of the micro heat dissipation plate 392, the size of the adaptation hole 39 is adapted to the size of the heat dissipation micro-tube 38, and a plurality of heat dissipation holes are arranged around the adaptation hole 39, the bottom of the micro heat dissipation plate 392 is fixedly connected with a second limiting plate 391, and the second limiting plate 391 can limit the position of the heat dissipation micro-pipe 38.

The utility model discloses in relate to circuit and electronic components and be prior art, technical personnel in the field can realize completely, need not proud, the utility model discloses the content of protection does not relate to the improvement to inner structure and method yet, need to explain, the utility model discloses the standard parts that use all can purchase from the market, and dysmorphism piece all can be customized according to the description of description and the record of attached drawing, and the concrete joining mode of each part all adopts conventional means such as ripe bolt, rivet, welding among the prior art, and machinery, part and equipment all adopt prior art, conventional model, inventor no longer detailed here.

And those not described in detail in this specification are well within the skill of those in the art.

When the cooling device works, the heat dissipation plate 33 is inserted into the connecting pipe 32 in the mounting plate 31 from the first limiting plate 34, then the ventilator 22 is started, the ventilator 22 is started to drive the rotating shaft 21 to rotate, the rotating shaft 21 rotates to drive the connecting shaft 23 fixedly connected with the rotating shaft to rotate, the connecting shaft 23 rotates to drive the 7-shaped sliding rod 292 to slide in the special-shaped groove 24 along the track of the special-shaped groove 24, the 7-shaped sliding rod 292 slides along the track of the special-shaped groove 24 to drive the connecting rod 293 to move, the connecting rod 293 moves to drive the extrusion plate to extrude cooling liquid, the cooling liquid is pushed into the drainage pipes 26 on two sides, the cooling liquid is sprayed onto the inclined flow plate 27 through the water outlet nozzle 28, flows into the top of the mounting plate 31 through the inclined flow plate 27 and flows into the surface of the heat dissipation plate 33 through the connecting pipe 32, the heat dissipation microtube 38 conducts the temperature to the heat dissipation plate 33 through the miniature heat dissipation plate 392, the cooling liquid flowing into the connecting pipe 32 to cool the heat dissipation plate 33, at the ventilator 22 exchanges the temperature of the heat dissipation chamber 3 with the external cold air, the cooling liquid flows into the through hole 35 arranged in the first limiting plate 34, and flows into the through groove 35, and is circularly extruded into the through groove 2.

It should be noted that, in this document, relational terms such as first and second, and the like are used solely to distinguish one entity or action from another entity or action without necessarily requiring or implying any actual such relationship or order between such entities or actions. Also, the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or apparatus.

Although embodiments of the present invention have been shown and described, it will be appreciated by those skilled in the art that changes, modifications, substitutions and alterations can be made in these embodiments without departing from the principles and spirit of the invention, the scope of which is defined in the appended claims and their equivalents.

Claims (6)

1. The utility model provides a microtubule array high efficiency heat exchanger, includes heat transfer case (1) and its top fixed connection's dust cover (4), its characterized in that: be provided with squeezing chamber (2) and heat dissipation chamber (3) in heat exchange box (1), heat dissipation chamber (3) are including mounting panel (31) of fixed connection on heat exchange box (1) inner wall, mounting panel (31) in-connection has a plurality of connecting pipes (32), sliding connection has heating panel (33) in mounting panel (31) and connecting pipe (32) is extended to the one end of connecting pipe (32), fixedly connected with limiting plate (34) on heat exchange box (1) bottom inner wall, a plurality of through-holes have been seted up on limiting plate (34) surface.

2. The micro-tube array type efficient heat exchanger as claimed in claim 1, wherein: a through groove (35) is formed in the first limiting plate (34), the water outlet of the through hole is in surface contact with the through groove (35), a water outlet (36) is communicated with the water outlet at one end of the through groove (35), and one end of the water outlet (36) extends into the squeezing chamber (2).

3. The micro-tube array type efficient heat exchanger as claimed in claim 1, wherein: drainage blanket (37) have been seted up at the top of mounting panel (31), sliding connection has heat dissipation micropipe (38) in heating panel (33), the surface contact of heat dissipation micropipe (38) has miniature heating panel (392), adaptation mouth (39) have been seted up on the surface of miniature heating panel (392), a plurality of thermovents have been seted up around adaptation mouth (39), the bottom fixedly connected with limiting plate two (391) of miniature heating panel (392).

4. The micro-tube array type efficient heat exchanger as claimed in claim 1, wherein: extrusion chamber (2) include axis of rotation (21) of being connected with heat transfer case (1) top inner wall rotation, top fixedly connected with ventilator (22) of axis of rotation (21), bottom fixedly connected with connecting axle (23) of axis of rotation (21), dysmorphism groove (24) have been seted up on the surface of connecting axle (23), fixedly connected with division board (25) on the inner wall of heat transfer case (1) bottom, the top of division board (25) and the bottom fixed connection of mounting panel (31).

5. The micro-tube array type efficient heat exchanger as claimed in claim 1, wherein: the equal fixedly connected with drainage tube (26) in surface on heat exchange box (1) left inner wall and division board (25) right side, the one end fixedly connected with diagonal flow board (27) of drainage tube (26), drainage tube (26) and diagonal flow board (27) intercommunication and delivery port intercommunication have water outlet spray head (28), one side fixedly connected with fixed block (29) of one of them drainage tube (26), seted up adaptation groove (291) in fixed block (29).

6. The micro-tube array type high-efficiency heat exchanger as claimed in claim 5, wherein: the improved drainage tube is characterized in that a 7-shaped sliding rod (292) is connected in the adaptation groove (291) in a sliding mode, one end of the 7-shaped sliding rod (292) extends out of the adaptation groove (291) and is in sliding connection with the inner wall of the special-shaped groove (24), the other end of the 7-shaped sliding rod (292) is fixedly connected with a connecting rod (293), two opposite sides of the connecting rod (293) are fixedly connected with an extrusion plate (294), one side of another drainage tube (26) is fixedly connected with a sliding block (295), a sliding groove is formed in the sliding block (295), and the inner surface of the sliding groove is in sliding connection with the outer surface of one of the connecting rods (293).

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