CN220248304U - Heat abstractor for be used for air compressor - Google Patents

Abstract

The utility model provides a heat dissipation device for an air compressor, and relates to the technical field of heat dissipation of air compressors. This device rotates through starting micro motor and controller, the dryer rotates, carries out the forced air cooling to the heating panel, and the both modes dispel the heat simultaneously, and after long-time use, the heating panel temperature at top is higher, and servo motor rotates this moment, and servo motor drives the driving gear and rotates, drives driven gear and rotates, drives heat-conducting plate and heating panel and rotates, overturns the heating panel of bottom to the top, and the heating panel of bottom soaks the temperature in the storage water tank inside lower, and the heat can be upwards mostly, so the lower heating panel of top temperature and heat-conducting plate absorb the air compressor body top heat that can be better to reach the better effect of heat dissipation.

Description

Heat abstractor for be used for air compressor

Technical Field

The utility model belongs to the technical field of air compressor heat dissipation, and particularly relates to a heat dissipation device for an air compressor.

Background

An air compressor is a device for compressing gas, the air compressor is similar to a water pump in structure, most of the air compressors are reciprocating pistons, rotating blades or rotating screws, centrifugal compressors are very large application programs, and in the use process of the air compressor, a heat dissipation device is often needed for heat dissipation treatment of the air compressor.

The prior publication number CN217950632U discloses a heat abstractor for an air compressor, which has the advantages of simple overall structure, realization of good heat dissipation effect of the air compressor, capability of carrying out multi-range heat dissipation on the air compressor, no need of consuming a large amount of time in the heat dissipation process of the air compressor, guarantee of the heat dissipation effect of the air compressor and improvement of the use efficiency and the use effect of the heat abstractor.

Based on the above, the present inventors found that the following problems exist: but the device radiates heat by means of air cooling alone, the radiating effect is not particularly good due to the single radiating mode, and the internal water quantity is fixed and always circulates due to the water cooling, so that the radiating effect is poor due to the fact that the water temperature rises after long-time use.

Accordingly, in view of the above, the present utility model has been made in view of the above-mentioned problems and disadvantages, and it is an object of the present utility model to provide a heat dissipating device for an air compressor, which is more practical.

Disclosure of Invention

In order to solve the technical problems, the utility model provides a heat dissipation device for an air compressor, which is used for solving the problem that the existing heat dissipation mode is single, so that the heat dissipation effect is poor.

The utility model provides a heat dissipating device for an air compressor, which is achieved by the following specific technical means:

the utility model provides a heat abstractor for air compressor, includes the shell body, shell body inner wall middle part is fixed with the air compressor body, the air inlet has been seted up to shell body top one side, the gas vent has been seted up in the penetration of shell body top opposite side, air inlet one side is fixed with first connecting block, first connecting block one end is fixed with micro motor, micro motor's power take off end is fixed with the dryer, shell body both ends middle part all runs through the rotation and is connected with the heat-conducting plate, the heat-conducting plate outer wall is fixed with the heating panel, two the heat-conducting plate middle part is fixed with the connecting rod, one of them heat-conducting plate one end is fixed with driven gear, shell body outer wall one end is fixed with the bracing piece, bracing piece one end bottom is fixed with servo motor, servo motor's power take off end is fixed with the driving gear, shell body inner wall bottom movable mounting has the storage water tank.

Further, the miniature motor is a double-shaft motor, two air cylinders are arranged, the two air cylinders are respectively positioned at two power output ends of the miniature motor, and the other ends of the two air cylinders are rotationally connected with the inner wall of the outer shell.

Further, grooves are formed in one side of each of the heat conducting plate and one side of the heat radiating plate in a penetrating mode, the grooves are used for dividing the heat conducting plate and the heat radiating plate into two equal parts, four connecting rods are arranged, and the four connecting rods are used for connecting the two heat conducting plates.

Further, the heating panel is provided with a plurality of, and is a plurality of the heating panel is the horizontal equidistance and arranges, the heating panel is the ring form, the heating panel top is located same horizontal plane with the dryer.

Further, the spout has been run through to shell body one end bottom, the inside sliding connection of spout has the storage water tank, storage water tank one end is fixed with the handle, the level height value of storage water tank top is less than the level height value of heating panel bottom.

Further, a controller is fixed on one side of the supporting rod and is electrically connected with the servo motor, and the controller is used for controlling the rotation of the servo motor.

Further, the driving gear and the driven gear are positioned on the same vertical plane, the driving gear and the driven gear are meshed with each other, and the number of teeth of the driven gear is equal to an integral multiple of the number of teeth of the driving gear.

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

1. according to the utility model, the micro motor and the controller are started, the air duct rotates to cool the heat dissipation plate, the heat dissipation plate is cooled in two modes, the temperature of the heat dissipation plate at the top is higher after the air conditioner is used for a long time, the servo motor rotates at the moment, the servo motor drives the driving gear to rotate, the driven gear to rotate, the heat conduction plate and the heat dissipation plate are driven to rotate, the heat dissipation plate at the bottom is turned to the top, the heat dissipation plate at the bottom is lower in soaking temperature in the water storage tank, and most of heat can be upwards, so that the heat dissipation plate and the heat conduction plate at the top with lower temperature can absorb the heat at the top of the air compressor body better, and therefore a better heat dissipation effect is achieved.

2. According to the utility model, the number of turns of the servo motor is controlled by the controller, so that the driven gear can just rotate for half a turn, after the servo motor is used for a long time, the temperature of the top heat dissipation plate is higher, at the moment, the servo motor rotates to drive the driving gear to rotate so as to drive the driven gear to rotate, the heat conduction plate and the heat dissipation plate to rotate, the bottom heat dissipation plate is lower in the water storage tank, meanwhile, partial water drops are attached to the outer wall of the bottom heat dissipation plate, air cooling is carried out through the air duct, water evaporation absorbs heat, the heat dissipation plate can absorb heat of the heat conduction plate and the air compressor body better, and water cooling heat dissipation can evaporate water to dissipate heat, so that the heat dissipation effect is further improved.

Drawings

Fig. 1 is a forty-five degree schematic view of the right side of the overall structure of the present utility model.

Fig. 2 is an enlarged schematic view of the structure of the portion a of fig. 1 according to the present utility model.

Fig. 3 is a schematic top view of the overall structure of the present utility model.

Fig. 4 is a schematic view of the internal part structure of the present utility model.

In the figure, the correspondence between the component names and the drawing numbers is:

1. an outer housing; 2. an air inlet; 3. an exhaust port; 4. a first connection block; 5. a micro motor; 6. an air duct; 7. an air compressor body; 8. a chute; 9. a water storage tank; 10. a handle; 11. a heat conductive plate; 12. a heat dissipation plate; 13. a connecting rod; 14. a groove; 15. a driven gear; 16. a support rod; 17. a controller; 18. a servo motor; 19. a driving gear.

Detailed Description

Embodiments of the present utility model are described in further detail below with reference to the accompanying drawings and examples. The following examples are illustrative of the utility model but are not intended to limit the scope of the utility model.

In the description of the present utility model, unless otherwise indicated, the meaning of "a plurality" is two or more; the terms "upper," "lower," "left," "right," "inner," "outer," "front," "rear," "head," "tail," and the like are used as an orientation or positional relationship based on that shown in the drawings, merely to facilitate description of the utility model and to simplify the description, and do not indicate or imply that the devices or elements referred to must have a particular orientation, be constructed and operated in a particular orientation, and therefore should not be construed as limiting the utility model. Furthermore, the terms "first," "second," "third," and the like are used for descriptive purposes only and are not to be construed as indicating or implying relative importance.

In the description of the present utility model, it should be noted that, unless explicitly specified and limited otherwise, the terms "connected," "connected," and "connected" are to be construed broadly, and may be either fixedly connected, detachably connected, or integrally connected, for example; can be mechanically or electrically connected; can be directly connected or indirectly connected through an intermediate medium. The specific meaning of the above terms in the present utility model will be understood in specific cases by those of ordinary skill in the art.

Examples:

as shown in fig. 1 to 4:

the utility model provides a heat radiator for an air compressor, which comprises an outer shell 1, wherein an air compressor body 7 is fixed in the middle of the inner wall of the outer shell 1, an air inlet 2 is formed in one side of the top of the outer shell 1, an air outlet 3 is formed in the other side of the top of the outer shell 1 in a penetrating way, a first connecting block 4 is fixed on one side of the air inlet 2, a micro motor 5 is fixed at one end of the first connecting block 4, an air duct 6 is fixed at the power output end of the micro motor 5, heat conducting plates 11 are connected in penetrating and rotating way at the middle of the two ends of the outer shell 1, heat radiating plates 12 are fixed on the outer walls of the heat conducting plates 11, connecting rods 13 are fixed in the middle of the two heat conducting plates 11, one end of one heat conducting plate 11 is fixed with a driven gear 15, a supporting rod 16 is fixed at one end of the outer wall of the outer shell 1, a servo motor 18 is fixed at the bottom of one end of the supporting rod 16, a driving gear 19 is fixed at the power output end of the servo motor 18, and a water storage tank 9 is movably mounted at the bottom of the inner wall of the outer shell 1.

Wherein, micro motor 5 is biax motor, and dryer 6 are provided with two, and two dryer 6 are located two power take off ends of micro motor 5 respectively, and two dryer 6 other ends rotate with shell body 1 inner wall and are connected, drive two dryer 6 through micro motor 5 and rotate, inhale the lower air of external temperature from air inlet 2, and dryer 6 length is longer, and dryer 6 is connected with shell body 1 inner wall, prevents to produce the vibration when rotating at a high speed.

Wherein, recess 14 has all been run through to heat conduction board 11 and heating panel 12 one side, and recess 14 is used for dividing heat conduction board 11 and heating panel 12 two equally, and connecting rod 13 is provided with four, and four connecting rods 13 are used for connecting two heat conduction boards 11, makes heat conduction board 11 divide into two through recess 14, prevents that heat conduction board 11 at top and heat conduction board 11 at bottom from carrying out heat transfer, will separate two heat conduction boards 11 of same horizontal plane after the back through connecting rod 13 and connect.

Wherein, heating panel 12 is provided with a plurality of, and a plurality of heating panels 12 are the horizontal equidistance and arrange, and heating panel 12 is the ring form, and heating panel 12 top and dryer 6 are located same horizontal plane, absorb the heat of heat-conducting plate 11 through heating panel 12, when rotating through dryer 6, carry out the forced air cooling to heating panel 12.

Wherein, spout 8 has been run through to shell body 1 one end bottom, spout 8 inside sliding connection has storage water tank 9, storage water tank 9 one end is fixed with handle 10, the level height value at storage water tank 9 top is less than the level height value of heating panel 12 bottom for heating panel 12 is located the bottom, inside heating panel 12 can soak storage water tank 9, the inside water of storage water tank 9 absorbs heat to heating panel 12, the heating panel 12 after being cooled down by storage water tank 9 rotates to the top, the heat can upwards mostly, so heating panel 12 and heat-conducting plate 11 that the top temperature is lower can be better absorb air compressor body 7 top heat.

Wherein, a controller 17 is fixed on one side of the support rod 16, the controller 17 is electrically connected with a servo motor 18, the controller 17 is used for controlling the rotation of the servo motor 18, and the controller 17 is used for controlling the servo motor 18 to intermittently rotate.

Wherein, the driving gear 19 and the driven gear 15 are located in the same vertical plane, the driving gear 19 and the driven gear 15 are engaged with each other, the servo motor 18 drives the driving gear 19 to rotate, and then drives the driven gear 15 to rotate, and drives the heat-conducting plate 11 and the heat-radiating plate 12 to rotate, the tooth number of the driven gear 15 is equal to an integer multiple of the tooth number of the driving gear 19, and the number of turns of the servo motor 18 is controlled by the controller 17, so that the driven gear 15 can just rotate for half a turn.

Specific use and action of the embodiment:

according to the utility model, a large amount of water is firstly added into the water storage tank 9, then the water storage tank 9 is inserted into the chute 8, when the air compressor body 7 works, the micro motor 5 and the controller 17 are started, the micro motor 5 drives the two air cylinders 6 to rotate, air with lower external temperature is sucked from the air inlet 2, the length of the air cylinder 6 is longer, the air cylinder 6 is connected with the inner wall of the outer shell 1, vibration is prevented from being generated when the air cylinder 6 rotates at high speed, the top of the heat dissipation plate 12 and the air cylinder 6 are positioned at the same horizontal plane, the heat of the heat conduction plate 11 is absorbed through the heat dissipation plate 12, when the air cylinder 6 rotates, the heat dissipation plate 12 is subjected to air cooling, meanwhile, the controller 17 is arranged to control the rotation number of the servo motor 18, so that the driven gear 15 can just rotate for half a circle, after long-time use, the temperature of the heat dissipation plate 12 at the top is higher, the servo motor 18 rotates, the servo motor 18 drives the driving gear 19 to rotate, the driven gear 15 is driven to rotate, the heat conduction plate 11 and the heat dissipation plate 12 are driven to rotate, the heat dissipation plate 12 at lower internal soaking temperature of the air compressor body 9, and part of water drops are adhered to the outer wall, and the heat absorption plate 12 is performed through the air cylinder 6, and the heat absorption plate 12 can absorb heat better.

The controller 17 is model ZD6209V22.

The embodiments of the utility model have been presented for purposes of illustration and description, and are not intended to be exhaustive or limited to the utility model in the form disclosed. Many modifications and variations will be apparent to those of ordinary skill in the art. The embodiments were chosen and described in order to best explain the principles of the utility model and the practical application, and to enable others of ordinary skill in the art to understand the utility model for various embodiments with various modifications as are suited to the particular use contemplated.

Claims (7)

1. The utility model provides a heat abstractor for air compressor, includes shell body (1), shell body (1) inner wall middle part is fixed with air compressor body (7), its characterized in that: air inlet (2) have been seted up on one side of shell body (1) top, gas vent (3) have been seted up in the other side of shell body (1) top, air inlet (2) one side is fixed with first connecting block (4), first connecting block (4) one end is fixed with micro motor (5), the power take off end of micro motor (5) is fixed with dryer (6), all run through in shell body (1) both ends middle part is connected with heat-conducting plate (11) in the running, heat-conducting plate (11) outer wall is fixed with heating panel (12), two heat-conducting plate (11) middle part is fixed with connecting rod (13), one of them heat-conducting plate (11) one end is fixed with driven gear (15), shell body (1) outer wall one end is fixed with bracing piece (16), bracing piece (16) one end bottom is fixed with servo motor (18), the power take off end of servo motor (18) is fixed with driving gear (19), shell body (1) inner wall bottom movable mounting has storage water tank (9).

2. A heat sink for an air compressor as defined in claim 1, wherein: the miniature motor (5) is a double-shaft motor, two air cylinders (6) are arranged, the two air cylinders (6) are respectively located at two power output ends of the miniature motor (5), and the other ends of the two air cylinders (6) are rotatably connected with the inner wall of the outer shell (1).

3. A heat sink for an air compressor as defined in claim 1, wherein: the heat conducting plate (11) and one side of the heat radiating plate (12) are respectively provided with a groove (14) in a penetrating mode, the grooves (14) are used for equally dividing the heat conducting plate (11) and the heat radiating plate (12), the connecting rods (13) are four, and the four connecting rods (13) are used for connecting the two heat conducting plates (11).

4. A heat sink for an air compressor as defined in claim 1, wherein: the cooling plates (12) are arranged in a plurality, the cooling plates (12) are horizontally and equidistantly distributed, the cooling plates (12) are in a circular ring shape, and the tops of the cooling plates (12) and the air cylinders (6) are located on the same horizontal plane.

5. A heat sink for an air compressor as defined in claim 1, wherein: the utility model discloses a heat radiation device, including shell body (1), spout (8) have been seted up in running through in shell body (1) one end bottom, spout (8) inside sliding connection has storage water tank (9), storage water tank (9) one end is fixed with handle (10), the level height value at storage water tank (9) top is less than the level height value of heating panel (12) bottom.

6. A heat sink for an air compressor as defined in claim 1, wherein: a controller (17) is fixed on one side of the supporting rod (16), the controller (17) is electrically connected with the servo motor (18), and the controller (17) is used for controlling the rotation of the servo motor (18).

7. A heat sink for an air compressor as defined in claim 1, wherein: the driving gear (19) and the driven gear (15) are positioned on the same vertical plane, the driving gear (19) and the driven gear (15) are meshed with each other, and the number of teeth of the driven gear (15) is equal to an integral multiple of the number of teeth of the driving gear (19).