CN220994146U - Heat dissipation type diamond abrasive disc - Google Patents

Abstract

The utility model belongs to the technical field of diamond grinding sheets, in particular to a heat-dissipation type diamond grinding sheet, which comprises a grinding sheet body, wherein a heat dissipation mechanism is arranged on the back surface of the grinding sheet body, and when the heat-dissipation type diamond grinding sheet is used, the grinding sheet body drives the heat dissipation mechanism to rotate at a high speed, and the heat dissipation mechanism guides out heat in the grinding sheet body. This heat dissipation type diamond abrasive disc, through setting up at the back-mounting cooling body of abrasive disc body, when utilizing cooling body's heat conduction board cooperation heat conduction ring to dispel the heat, deflect the heat conduction board, the windage when having reduced abrasive disc body high-speed rotation, the heat conduction board after utilizing the deflection is formed with funnel-shaped wind channel with the abrasive disc body simultaneously, and then when abrasive disc body high-speed rotation, make the air current follow the heat conduction board and press close to the one end outflow of abrasive disc body, and then be convenient for directly carry out forced air cooling to the abrasive disc body, thereby make cooling body have the characteristics of being convenient for reduce cooling body windage when being convenient for to abrasive disc.

Description

Heat dissipation type diamond abrasive disc

Technical Field

The utility model relates to the technical field of diamond grinding sheets, in particular to a heat dissipation type diamond grinding sheet.

Background

The diamond grinding disc comprises a wet grinding disc, a dry grinding disc and a hard grinding disc, is mainly used for processing operations of granite, marble, artificial stone and the like, and the quality of the diamond grinding disc directly influences the quality of products, so that the diamond grinding disc has extremely strict requirements on the diamond grinding disc, and the diamond grinding disc used at present is various in variety.

The heat dissipation type diamond abrasive disc (publication number: CN 210616245U) disclosed on the Chinese patent website solves the technical problems that the service life of the diamond abrasive disc is seriously affected by long-time use, the diamond abrasive disc is inconvenient to replace and inconvenient to use, although the heat dissipation effect of the traditional diamond abrasive disc is poor, the following problems still exist:

In the in-service use process, the diamond abrasive disc drives the air baffle plate to rotate at the same speed, and the surface of the air baffle plate is approximately perpendicular to the surface of the air flow, so that the air baffle plate brings great resistance to the rotation of the diamond abrasive disc, and although part of air flow can flow out through the vent holes, the rotation of the diamond abrasive disc is still hindered, and meanwhile, the air baffle plate is vertically installed, so that the specification of the air baffle plate is limited by the specification of the polishing machine, and the two ends of the air baffle plate are respectively contacted with the back surface of the diamond abrasive disc and the surface of the polishing machine, so that the use is affected.

Disclosure of utility model

Based on the technical problem that the existing diamond grinding disc heat dissipation mechanism is inconvenient to use, the utility model provides a heat dissipation type diamond grinding disc.

The heat dissipation type diamond abrasive disc comprises an abrasive disc body, wherein a heat dissipation mechanism is arranged on the back surface of the abrasive disc body, and when the abrasive disc is used, the abrasive disc body drives the heat dissipation mechanism to rotate at a high speed, the heat dissipation mechanism conducts out heat in the abrasive disc body outwards, and the conducted out heat is radiated outwards in the high-speed rotation action of the heat dissipation mechanism.

Preferably, the heat dissipation mechanism comprises a temperature guide ring, a temperature guide groove is formed in the back surface of the grinding disc body, the inner wall of the temperature guide groove is fixedly connected with one end surface of the temperature guide ring, the other end surface of the temperature guide ring is positioned outside the temperature guide groove, threaded rods are slidably inserted into the side wall surfaces of the temperature guide ring, and a plurality of threaded rods are distributed in an annular array on the surface of the temperature guide ring by taking the axis of the temperature guide ring as the array center.

Through above-mentioned technical scheme, utilize the heat conduction ring to outwards derive the high temperature that the abrasive disc body during operation produced to the one end that exposes through the heat conduction ring is convenient for cool down.

Preferably, one end surface threaded connection of threaded rod has the nut, the surface of nut supports tightly with the inside wall slip of heat conduction ring, the other end fixedly connected with heat conduction board of threaded rod, heat conduction board, threaded rod and heat conduction ring's material are copper metal.

Through above-mentioned technical scheme, utilize at the surface mounting a plurality of threaded rods of heat conduction ring to be convenient for derive the heat of lead Wen Huanna through threaded rod and surface structure thereof.

Preferably, one end of the temperature guide plate is close to the back of the grinding disc body, a heat dissipation hole is formed in the surface of the side wall of the temperature guide plate, a movable groove is formed in the edge of the temperature guide plate, and the inner wall of the movable groove is slidably connected with the movable plate.

Through the technical scheme, the air duct on the surface of the temperature guide plate is increased by utilizing the radiating holes, so that the volatilization of heat in the temperature guide plate is facilitated.

Preferably, the surface of the movable plate is fixedly connected with a sliding block, the inner wall of the movable groove is provided with a sliding groove, and the inner wall of the sliding groove is in sliding connection with the surface of the sliding block.

Through above-mentioned technical scheme, utilize slider and spout swing joint fly leaf and heat-conducting plate to the fly leaf of being convenient for is at the surface activity of heat-conducting plate, and then avoids impurity at the surface joint of fly leaf.

Preferably, the side wall surface of the temperature guide ring is provided with a communication hole, two openings of the communication hole are respectively positioned on the inner side wall and the outer side wall of the temperature guide ring, and two adjacent communication holes are respectively positioned on two sides of the threaded rod.

Through the technical scheme, the inner side of the temperature guide ring is communicated with the outside by the aid of the communication holes, so that air circulation in the temperature guide ring is facilitated.

The beneficial effects of the utility model are as follows:

Through setting up at the back-mounting cooling body of abrasive disc body, when utilizing cooling body's heat conduction board cooperation heat conduction ring to dispel the heat, deflect the heat conduction board, the windage when having reduced abrasive disc body high-speed rotation, the heat conduction board after utilizing the deflection is formed with funnel-shaped wind channel with the abrasive disc body simultaneously, and then when abrasive disc body high-speed rotation for the air current flows from the one end that the abrasive disc body was pressed close to the heat conduction board, and then is convenient for directly carry out forced air cooling to the abrasive disc body, thereby make cooling body have the characteristics of being convenient for reduce cooling body windage when being convenient for dispel the heat to the abrasive disc.

Drawings

Fig. 1 is a schematic diagram of a heat dissipation type diamond abrasive disc according to the present utility model;

Fig. 2 is an exploded view of a heat dissipation type diamond abrasive disc body structure according to the present utility model;

Fig. 3 is a cross-sectional view of a guide Wen Huanjie of a heat-dissipating diamond grinding disc according to the present utility model;

fig. 4 is an exploded view of a heat conducting plate structure of a heat dissipation type diamond abrasive disc according to the present utility model.

In the figure: 1. a lapping body; 2. a heat dissipation mechanism; 21. a temperature guide ring; 22. a threaded rod; 23. a nut; 24. a temperature guide plate; 25. a heat radiation hole; 26. a movable groove; 27. a movable plate; 271. a slide block; 28. a communication hole; 3. a temperature guiding groove.

Detailed Description

The following description of the embodiments of the present utility model will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present utility model, but not all embodiments.

Referring to fig. 1-4, a heat dissipation type diamond abrasive disc comprises an abrasive disc body 1, wherein a heat dissipation mechanism 2 is arranged on the back surface of the abrasive disc body 1, when the abrasive disc is used, the abrasive disc body 1 drives the heat dissipation mechanism 2 to rotate at a high speed, the heat dissipation mechanism 2 conducts out heat inside the abrasive disc body 1 outwards, and the conducted heat is radiated outwards in the high-speed rotation action of the heat dissipation mechanism 2.

In order to be with the intraductal high Wen Daochu of abrasive disc body 1, set up heat dissipation mechanism 2 and including the heat conduction ring 21, the heat conduction groove 3 has been seted up to the back of abrasive disc body 1, the inner wall of heat conduction groove 3 is fixed with the one end surface of heat conduction ring 21, the other end surface of heat conduction ring 21 is located the outside of heat conduction groove 3, the lateral wall surface slip grafting of heat conduction ring 21 has threaded rod 22, a plurality of threaded rods 22 are in the surface of heat conduction ring 21 and are the array distribution of annular array center with the axis of heat conduction ring 21, utilize the heat conduction ring 21 to outwards derive the high temperature that abrasive disc body 1 during operation produced, thereby be convenient for cool down through the one end that the heat conduction ring 21 exposes, the one end surface threaded connection of threaded rod 22 has nut 23, the surface of nut 23 is in tight with the inside wall slip of heat conduction ring 21, the other end fixedly connected with of threaded rod 22 heat conduction plate 24, the material of threaded rod 22 and heat conduction ring 21 is copper metal, utilize the surface mounting a plurality of threaded rods 22, thereby be convenient for derive heat in the heat conduction ring 21 through heat conduction ring 21.

In order to volatilize the heat in the heat dissipation mechanism 2, the one end at the heat conduction board 24 is pressed close to the back of abrasive disc body 1, the louvre 25 has been seted up on the lateral wall surface of heat conduction board 24, movable groove 26 has been seted up to the edge of heat conduction board 24, movable groove 26 inner wall sliding connection has fly leaf 27, utilize louvre 25 to increase the wind channel on heat conduction board 24 surface, thereby be convenient for volatilize the heat in the heat conduction board 24, the fixed surface of fly leaf 27 is connected with slider 271, the spout has been seted up to the inner wall of movable groove 26, the inner wall and the surface sliding connection of slider 271, utilize slider 271 and spout swing joint fly leaf 27 and heat conduction board 24, thereby be convenient for the surface activity of fly leaf 27 at heat conduction board 24, and then avoid the surperficial joint of impurity at fly leaf 27.

Through setting up at the back-mounting cooling mechanism 2 of abrasive disc body 1, when utilizing the heat dissipation of the heat conduction ring 21 of the heat conduction board 24 cooperation of cooling mechanism 2, deflect the heat conduction board 24, the windage when having reduced abrasive disc body 1 high-speed rotation, the while utilizes the heat conduction board 24 after the deflection to be formed with funnel-shaped wind channel with abrasive disc body 1, and then when abrasive disc body 1 high-speed rotation, make the air current follow the one end outflow of heat conduction board 24 press close to abrasive disc body 1, and then be convenient for directly carry out forced air cooling to abrasive disc body 1, thereby make cooling mechanism 2 have the characteristics of being convenient for reduce cooling mechanism 2 windage when being convenient for dispel the heat to the abrasive disc.

And the side wall surface of the heat conducting ring 21 is provided with a communication hole 28, two openings of the communication hole 28 are respectively positioned on the inner side wall and the outer side wall of the heat conducting ring 21, two adjacent communication holes 28 are respectively positioned on two sides of the threaded rod 22, and the inner side of the heat conducting ring 21 is communicated with the outside by utilizing the communication hole 28, so that the air circulation in the heat conducting ring 21 is facilitated.

Working principle:

When in use, the threaded rod 22 is inserted into the surface of the temperature guide ring 21, and the temperature guide plate 24 is adjusted to deflect according to the rotation direction of the grinding disc body 1 during operation, so that the air inlet end opening of the surface of the temperature guide plate 24 is larger than the air outlet end opening of the surface of the temperature guide plate 24, the end of the threaded rod 22 is in threaded connection with the nut 23, and the surface of the nut 23 and one end surface of the temperature guide plate 24 are respectively abutted against and fixed with two ends of the temperature guide ring 21;

Install abrasive disc body 1 on the mechanical surface of polishing, the mechanical high-speed rotation of abrasive disc body 1 and cooling mechanism 2 of driving of polishing, the high temperature that abrasive disc body 1 during operation produced passes through the outside transmission of heat conduction ring 21, and the high temperature in the heat conduction ring 21 passes through threaded rod 22 and heat conduction board 24 outwards transmission, and the air current gets into the one end that heat conduction board 24 pressed close to abrasive disc body 1 from the one end that heat conduction board 24 kept away from abrasive disc body 1 to promote the high temperature on heat conduction board 24 surface and abrasive disc body 1 surface high temperature volatilize.

The foregoing is only a preferred embodiment of the present utility model, but the scope of the present utility model is not limited thereto, and any person skilled in the art, who is within the scope of the present utility model, should make equivalent substitutions or modifications according to the technical scheme of the present utility model and the inventive concept thereof, and should be covered by the scope of the present utility model.

Claims (1)

1. The utility model provides a heat dissipation formula diamond abrasive disc, includes abrasive disc body (1), its characterized in that: the back of the abrasive disc body (1) is provided with a heat dissipation mechanism (2), when the abrasive disc is used, the abrasive disc body (1) drives the heat dissipation mechanism (2) to rotate at a high speed, the heat dissipation mechanism (2) conducts out the heat in the abrasive disc body (1) outwards, and the conducted out heat is radiated outwards in the high-speed rotation action of the heat dissipation mechanism (2);

The heat dissipation mechanism (2) comprises a temperature guide ring (21), a temperature guide groove (3) is formed in the back surface of the grinding disc body (1), the inner wall of the temperature guide groove (3) is fixedly connected with one end surface of the temperature guide ring (21), the other end surface of the temperature guide ring (21) is positioned outside the temperature guide groove (3), threaded rods (22) are slidably inserted into the side wall surface of the temperature guide ring (21), and a plurality of threaded rods (22) are distributed in an annular array on the surface of the temperature guide ring (21) by taking the axis of the temperature guide ring (21) as the array center;

One end surface of the threaded rod (22) is in threaded connection with a nut (23), the surface of the nut (23) is in sliding abutting connection with the inner side wall of the temperature guide ring (21), the other end of the threaded rod (22) is fixedly connected with a temperature guide plate (24), and the temperature guide plate (24), the threaded rod (22) and the temperature guide ring (21) are all made of copper metal;

One end of the temperature guide plate (24) is close to the back surface of the grinding disc body (1), a heat dissipation hole (25) is formed in the side wall surface of the temperature guide plate (24), a movable groove (26) is formed in the edge of the temperature guide plate (24), and a movable plate (27) is connected to the inner wall of the movable groove (26) in a sliding mode;

The surface of the movable plate (27) is fixedly connected with a sliding block (271), the inner wall of the movable groove (26) is provided with a sliding groove, and the inner wall of the sliding groove is in sliding connection with the surface of the sliding block (271);

The side wall surface of the heat conducting ring (21) is provided with a communication hole (28), two openings of the communication hole (28) are respectively positioned on the inner side wall and the outer side wall of the heat conducting ring (21), and two adjacent communication holes (28) are respectively positioned on two sides of the threaded rod (22).