CN219244324U - High-flow and high-efficiency internal circulation air cooling structure - Google Patents

Abstract

The utility model discloses a high-flow high-efficiency internal circulation air cooling structure, which relates to the technical field of air cooling equipment and comprises a bottom frame, wherein a fixed seat is fixedly arranged at the upper end of the bottom frame, a double-shaft motor is fixedly arranged at the upper end of the fixed seat, a fan is fixedly arranged at the front end output end of the double-shaft motor, a radiator is fixedly arranged at the front end of the fan, a plurality of radiating plates are fixedly arranged in the radiator, two clamping grooves are respectively arranged at the top and the bottom of the radiating plates, a water injection cover is fixedly arranged at one side of the radiator, a water outlet cover is fixedly arranged at the other side of the radiator, a conveying pump is fixedly arranged at the rear end output end of the double-shaft motor, a radiator water injection pipe is fixedly connected at one side of the water injection cover and the conveying pump, and a radiator water outlet pipe is fixedly connected at one end of a circulating water pipe in a vacuum furnace wall. A plurality of radiating fins are arranged on the radiating plate in the radiator, so that the heat of the cooling water entering the radiating plate can be conducted, the radiating capacity of the whole radiating plate is additionally increased, and the radiating effect is improved.

Description

High-flow and high-efficiency internal circulation air cooling structure

Technical Field

The utility model relates to the technical field of air cooling equipment, in particular to a high-flow and high-efficiency internal circulation air cooling structure.

Background

The vacuum furnace is characterized in that a vacuum system is utilized in a specific space of the furnace chamber, namely, partial substances in the furnace chamber are discharged, so that the pressure in the furnace chamber is smaller than a standard atmospheric pressure, the space in the furnace chamber is in a vacuum state, and when the vacuum furnace is used, a circulating cooling water channel is arranged in the furnace wall, so that the temperature of the furnace wall is reduced, a large amount of heat is prevented from being conducted to the furnace wall, and the risk of scalding caused by the fact that personnel touch the furnace wall is avoided;

and generally when cooling down the circulating water in this cooling water course, can adopt the fan to cool down the cooling water, and this kind of cooling mode is after the cooling water that has certain temperature passes through the short forced air cooling, because the contact time with the radiator is short, and then can't carry out a heat dissipation to the cooling water fast.

Disclosure of Invention

The utility model aims to provide a high-flow and high-efficiency internal circulation air cooling structure, which can effectively solve the problems in the background technology.

In order to achieve the above purpose, the technical scheme adopted by the utility model is as follows:

the utility model provides a high-flow efficient inner loop forced air cooling structure, includes the chassis, chassis upper end fixed mounting has the fixing base, fixing base upper end fixed mounting has the biax motor, biax motor front end output fixed mounting has the fan, fan front end fixed mounting has the radiator, fixed mounting has a plurality of heating panels in the radiator, two draw-in grooves have all been seted up to heating panel top and bottom, radiator one side fixed mounting has the water injection cover, radiator opposite side fixed mounting has the play water cover, biax motor rear end output fixed mounting has the delivery pump, water injection cover and delivery pump one side fixedly connected with radiator water injection pipe, the one end fixedly connected with radiator outlet pipe of the circulating water pipe in play water cover and the vacuum furnace wall, the delivery pump opposite side is located the water injection cover fixed mounting who is located radiator water injection pipe below position has the moisturizing valve, two be equipped with compensation mechanism between the heating panel, two compensation mechanism includes two install the curb plate through two arc connecting rod fixed mounting have a plurality of fins between the installation curb plate, two opposite side plates are installed two movable mounting pull rods are located two side plates.

As a further optimization scheme of the utility model, a first mounting groove is formed in one side of each of the two arc-shaped connecting rods, opposite to the heat dissipation plate, a slot is formed in the inner side of the first mounting groove, and a wiping strip is arranged in the first mounting groove.

As a further optimization scheme of the utility model, the cutting strip is fixedly arranged on one side of the wiping strip relative to the arc-shaped connecting rod, and the cutting strip is installed in the slot in a penetrating way.

As a further optimization scheme of the utility model, two opposite sides of the installation side plates are respectively provided with a second installation groove, and the top and the bottom in the second installation groove are respectively provided with a first sliding port and a jack.

As a further optimization scheme of the utility model, a first lock tongue block is fixedly arranged at the opposite and separated end of each of the two mounting rods, a second lock tongue block is fixedly arranged at one side of each of the two mounting rods, telescopic grooves are respectively formed in the opposite end of each of the two mounting rods, connecting shafts are installed in the two telescopic grooves in a penetrating manner, supporting springs are sleeved on the connecting shafts between the two mounting rods, and the first lock tongue blocks penetrate through corresponding insertion holes and are installed in the clamping grooves in a penetrating manner.

As a further optimization scheme of the utility model, the two ends of the pull rod are fixedly provided with the second sliding ports, the second sliding ports are slidably arranged in the corresponding first sliding ports, and the pull rod is fixedly provided with two third lock tongue blocks relative to one side of the installation rod.

As a further optimization scheme of the utility model, the heat dissipation fin is in a hollow state, and a plurality of penetrating air inlets are formed in two sides of the heat dissipation fin.

Compared with the prior art, the utility model has the following beneficial effects:

according to the high-flow high-efficiency internal circulation air cooling structure, the plurality of radiating fins are arranged on the radiating plate in the radiator, so that the heat of cooling water entering the radiating plate can be conducted, the radiating capacity of the whole radiating plate is additionally improved, and the radiating effect is improved.

Drawings

FIG. 1 is a schematic diagram of the main structure of the present utility model;

FIG. 2 is a split view of a radiator mechanism of the present utility model;

FIG. 3 is an enlarged view of FIG. 2 at A;

FIG. 4 is a split view of a heat sink structure according to the present utility model;

FIG. 5 is an enlarged view at B in FIG. 4;

FIG. 6 is an enlarged view at C in FIG. 4;

fig. 7 is a schematic view of the structure of the mounting bar of the present utility model.

In the figure: 1. a chassis; 2. a fixing seat; 3. a biaxial motor; 4. a blower; 5. a heat sink; 6. a heat dissipation plate; 7. a clamping groove; 8. a water injection cover; 9. a water outlet cover; 10. radiator water injection pipe; 11. a transfer pump; 12. a radiator outlet pipe; 13. a water replenishing valve; 14. a water outlet pipe of the vacuum furnace; 15. a compensation mechanism; 16. installing a side plate; 17. a heat dissipating fin; 18. an arc-shaped connecting rod; 19. a mounting rod; 20. a pull rod; 21. penetrating the air port; 22. a first mounting groove; 23. a slot; 24. a wiping strip; 25. cutting; 26. a second mounting groove; 27. a first sliding port; 28. a jack; 29. a first latch bolt block; 30. a second latch bolt block; 31. a telescopic slot; 32. a connecting shaft; 33. a support spring; 34. a second sliding port; 35. and a third bolt block.

Detailed Description

The utility model is further described in connection with the following detailed description, in order to make the technical means, the creation characteristics, the achievement of the purpose and the effect of the utility model easy to understand.

As shown in fig. 1-7, the high-flow high-efficiency internal circulation air cooling structure provided by the utility model comprises a bottom frame 1, a fixing seat 2 is fixedly arranged at the upper end of the bottom frame 1, a double-shaft motor 3 is fixedly arranged at the upper end of the fixing seat 2, a fan 4 is fixedly arranged at the output end of the front end of the double-shaft motor 3, a radiator 5 is fixedly arranged at the front end of the fan 4, a plurality of radiating plates 6 are fixedly arranged in the radiator 5, two clamping grooves 7 are respectively formed in the top and the bottom of the radiating plates 6, a water injection cover 8 is fixedly arranged at one side of the radiator 5, a water outlet cover 9 is fixedly arranged at the other side of the radiator 5, a conveying pump 11 is fixedly arranged at the output end of the rear end of the double-shaft motor 3, a radiator water injection pipe 10 is fixedly connected with one side of the water injection cover 8 and one side of the conveying pump 11, a radiator water outlet pipe 12 is fixedly connected with one end of the water outlet cover 9 and one end of a circulating water pipe in a vacuum furnace wall, a vacuum furnace water outlet pipe 14 is fixedly connected with the other end of the conveying pump 11, a water supplementing valve 13 is fixedly arranged at the other side of the conveying pump 11 and the other side of the circulating water pipe of the vacuum furnace wall, a compensating mechanism 15 is arranged between the two radiating plates 6, the two side plates 16 are respectively provided with two compensating mechanisms 16, two side plates 16 are respectively, two side plates 16 are fixedly arranged at two sides, two side plates 16 are respectively, two side rods are fixedly arranged at two sides of the connecting rods are movably, two side 19 are respectively, two side 19 are fixedly arranged, and two side 19 are fixedly, and two side 19 are respectively, and two side 19 are fixedly, and are movably, and are fixedly connected.

The two arc connecting rods 18 are provided with a first mounting groove 22 corresponding to one side of the heat dissipation plate 6, the inner side of the first mounting groove 22 is provided with a slot 23, and the first mounting groove 22 is internally provided with a wiping strip 24.

The wiping strip 24 is fixedly provided with a cutting 25 relative to one side of the arc-shaped connecting rod 18, and the cutting 25 is installed in the slot 23 in a penetrating way;

further, the wiping strip 24 can clean dust on the surface of the heat dissipation plate 6 when the heat dissipation fins 17 are detached.

The opposite sides of the two mounting side plates 16 are respectively provided with a second mounting groove 26, and the top and the bottom in the second mounting groove 26 are respectively provided with a first sliding port 27 and a jack 28.

The first spring bolt piece 29 is fixedly installed at one end, away from each other, of each of the two mounting rods 19, the second spring bolt piece 30 is fixedly installed at one side of each of the mounting rods 19, the telescopic grooves 31 are respectively formed in the opposite ends of the two mounting rods 19, the connecting shafts 32 are installed in the two telescopic grooves 31 in a penetrating mode, the supporting springs 33 are sleeved on the connecting shafts 32 between the two mounting rods 19, and the first spring bolt piece 29 penetrates through the corresponding insertion holes 28 to be installed in the clamping grooves 7 in a penetrating mode.

The two ends of the pull rod 20 are fixedly provided with second sliding openings 34, the second sliding openings 34 are slidably arranged in the corresponding first sliding openings 27, and two third lock tongue blocks 35 are fixedly arranged on one side of the pull rod 20 opposite to the mounting rod 19;

further, when the pull rod 20 pulls the mounting side plate 16, the first lock tongue block 29 is synchronously unlocked, so that the mounting side plate 16 is facilitated to drive the radiating fins to be pulled out from between the two radiating plates 6.

The heat dissipation fin 17 is in a hollow state, and a plurality of penetrating air inlets 21 are formed in two sides of the heat dissipation fin 17;

further, by the inclined surface structure of the heat radiating fin 17, the wind resistance can be reduced, and simultaneously, the heat of the heat dissipation plate 6 is rapidly conducted out.

When the internal circulation air cooling structure is used, after cooling water in the vacuum furnace wall is pumped into the heat dissipation plate 6 in the radiator 5 through the delivery pump 11 and the vacuum furnace water outlet pipe 14, heat of the cooling water is conducted to the heat dissipation plate 6 and the heat dissipation fins 17, and then the fan 4 is used for rapidly circulating air between the heat dissipation plate 6 and the clamping groove 7, heat conducted by well cooling water is rapidly removed, and the heat is recycled to a water channel in the vacuum furnace wall through the radiator water outlet pipe 12;

after dust is accumulated on the surface of the heat dissipation plate 6, normal heat dissipation of the heat dissipation plate 6 is affected, only the pull rod 20 on one side of the two mounting side plates 16 is pulled towards the direction of the mounting rods 19, then the pull rod 20 drives the two third lock tongue blocks 35 to respectively squeeze the second lock tongue blocks 30 on one side of the two mounting rods 19, then the two second lock tongue blocks 30 respectively drive the corresponding mounting rods 19 to move relatively, the telescopic slots 31 in the two mounting rods 19 move on the connecting shafts 32 and compress the supporting springs 33, then the two mounting rods 19 respectively drive the first lock tongue blocks 29 on one end to be separated from the clamping slots 7 in the heat dissipation plate 6, the mounting side plates 16 can be pulled to move out from between the two heat dissipation plates 6 through the pull rod 20, the mounting side plates 16 drive the heat dissipation fins 17 to move out from between the two heat dissipation plates 6 through the arc-shaped connecting rods 18, and meanwhile, the wiping strips 24 in the two arc-shaped connecting rods 18 wipe dust on the surfaces of the heat dissipation plates 6.

The foregoing has shown and described the basic principles and main features of the present utility model and the advantages of the present utility model. It will be understood by those skilled in the art that the present utility model is not limited to the embodiments described above, and that the above embodiments and descriptions are merely illustrative of the principles of the present utility model, and various changes and modifications may be made without departing from the spirit and scope of the utility model, which is defined in the appended claims. The scope of the utility model is defined by the appended claims and equivalents thereof.

Claims (7)

1. The utility model provides a high-flow efficient inner loop forced air cooling structure, includes chassis (1), chassis (1) upper end fixed mounting has fixing base (2), fixing base (2) upper end fixed mounting has biax motor (3), biax motor (3) front end output fixed mounting has fan (4), fan (4) front end fixed mounting has radiator (5), fixed mounting has a plurality of heating panels (6) in radiator (5), two draw-in grooves (7) have all been seted up to heating panel (6) top and bottom, radiator (5) one side fixed mounting has water injection cover (8), radiator (5) opposite side fixed mounting has water outlet cover (9), biax motor (3) rear end output fixed mounting has delivery pump (11), water injection cover (8) and delivery pump (11) one side fixedly connected with radiator water injection pipe (10), water outlet pipe's (12) of the one end fixedly connected with circulating water pipe in vacuum oven wall, the other side of delivery pump (11) and vacuum oven wall's the other end fixedly connected with water injection pipe (14), water injection cover (8) are located water injection door (13) below its fixed mounting, water injection door (13) are located its water injection door (13). A compensation mechanism (15) is arranged between the two radiating plates (6), the compensation mechanism (15) comprises two mounting side plates (16), a plurality of radiating fins (17) are fixedly mounted between the two mounting side plates (16) through two arc-shaped connecting rods (18), two mounting rods (19) are movably mounted on the opposite sides of the two mounting side plates (16), and a pull rod (20) is movably mounted in the mounting side plate (16) on one side of each mounting rod (19).

2. The high-flow and high-efficiency internal circulation air cooling structure according to claim 1, wherein: the two arc-shaped connecting rods (18) are respectively provided with a first mounting groove (22) relative to one side of the radiating plate (6), the inner sides of the first mounting grooves (22) are provided with slots (23), and wiping strips (24) are arranged in the first mounting grooves (22).

3. The high-flow and high-efficiency internal circulation air cooling structure according to claim 2, wherein: the wiping strip (24) is fixedly provided with an inserting strip (25) relative to one side of the arc-shaped connecting rod (18), and the inserting strip (25) is installed in the slot (23) in a penetrating mode.

4. A high flow and high efficiency internal circulation air cooling structure according to claim 3, wherein: the two opposite sides of the installation side plates (16) are respectively provided with a second installation groove (26), and the top and the bottom in the second installation grooves (26) are respectively provided with a first sliding port (27) and a jack (28).

5. The high-flow and high-efficiency internal circulation air cooling structure according to claim 4, wherein: two installation pole (19) are all fixed mounting from one end mutually has first spring bolt piece (29), installation pole (19) one side fixed mounting has second spring bolt piece (30), and two expansion tank (31) have been seted up respectively to installation pole (19) relative one end, two interlude is installed connecting axle (32) in expansion tank (31), are located two the cover is equipped with supporting spring (33) on connecting axle (32) between installation pole (19), just first spring bolt piece (29) pass corresponding jack (28) interlude and install in draw-in groove (7).

6. The high-flow and high-efficiency internal circulation air cooling structure according to claim 5, wherein: the two ends of the pull rod (20) are fixedly provided with second sliding openings (34), the second sliding openings (34) are slidably arranged in the corresponding first sliding openings (27), and two third lock tongue blocks (35) are fixedly arranged on one side of the pull rod (20) opposite to the mounting rod (19).

7. The high-flow and high-efficiency internal circulation air cooling structure according to claim 1, wherein: the inside of the radiating fin (17) is in a hollow state, and a plurality of penetrating air inlets (21) are formed in two sides of the radiating fin (17).

Images