CN213590394U - Water-cooling heat dissipation system of emulsifying machine - Google Patents

Abstract

The utility model provides an emulsion machine water-cooling system. This technical scheme has abandoned the heat radiation structure of double-layered cover formula, places a part of refrigerant circulation pipeline in jar body in, has improved its specific configuration simultaneously. Specifically, the utility model discloses utilize the inlet tube to introduce refrigerant water, the inlet tube bottom adopts to bear the weight of the dish and play simultaneously and bear and seal the effect, and the inlet tube side sets up the horizontally radiant tube, both increases heat transfer area, spreads over each position in the jar body with the heat transfer surface again. The refrigerant flowing through the radiation pipe enters a water return pipe and finally flows back from the lower port; be equipped with the bellying on the wet return surface, help further increase heat transfer area. Meanwhile, the utility model discloses with the homogenizing head and the suitable side of actuating mechanism and move, can ensure that the refrigerant system can not influence its constitution. Use the utility model discloses, can make the heat-transfer face distribute around the heat production site, effectively increased heat transfer area simultaneously, have better radiating effect than conventional jacket structure.

Description

Water-cooling heat dissipation system of emulsifying machine

Technical Field

The utility model relates to an emulsion machine technical field, concretely relates to emulsion machine water-cooling heat dissipation system.

Background

The emulsifying machine is a device which cuts, disperses and impacts materials through the high-speed rotation of the homogenizing head, so that the particle size of the materials is smaller, and the oil and water are enabled to be melted to achieve the emulsifying effect. The oil-soluble polymer is widely applied to the fields of food, medicine, skin care products and the like, and is also commonly used in the fields of petrochemical industry, paint coating and the like.

In the emulsifying process, high-speed shearing of a cutter head and a material is involved, mechanical shearing and friction are accompanied with heat generation, and if certain heat dissipation measures are not taken, the material temperature is easily overhigh. Especially for fluid or semisolid with poor fluidity, the temperature rise is very obvious, and if the thermal stability of the material is poor (such as protein, sugar and the like), the material denaturation problem is easy to occur. Among the prior art, the emulsion machine generally is equipped with heat radiation structure, but mostly is the jacket mode, adopts the cladding of jacket structure in emulsion machine jar body periphery promptly, utilizes the refrigerant water to carry out the heat transfer to a jar external wall. Although the mode has a certain heat dissipation effect, the heat exchange surface of the mode is positioned on the outer wall of the tank body, and the position where heat is generated is generally positioned in the center of the tank body (namely the contact position of the homogenizing head and the material), so that the cooling effect is not ideal.

Disclosure of Invention

The utility model discloses aim at to prior art's technical defect, provide an emulsion machine water-cooling system to the conventional water-cooling of solving the emulsion machine presss from both sides the cover, the not ideal enough technical problem of its cooling effect.

In order to realize the technical purpose, the utility model adopts the following technical scheme:

the water-cooling heat dissipation system of the emulsifying machine comprises a tank body, supporting legs, a bearing seat, a rotating shaft, a driven belt pulley, a belt, a driving belt pulley, a motor, a homogenizing head, a water inlet pipe, a bearing disc, a radiation pipe, a water return pipe, a protruding part and a port, wherein the supporting legs are fixedly connected to the lower end of the tank body, the bearing seat is fixedly connected to the upper end of the tank body, the rotating shaft is arranged on the bearing seat through a bearing, the rotating shaft longitudinally extends into the tank body, the homogenizing head is fixedly connected to the rotating shaft, and the homogenizing head is positioned in the; the top end of the rotating shaft is fixedly connected with a driven belt pulley, the driven belt pulley is in transmission connection with a driving belt pulley through a belt, and the driving belt pulley is in transmission connection with a main shaft of a motor; the inlet tube vertically stretches into to jar internal portion, and fixedly connected with bears the dish on the inner wall of the jar body, bears the dish and supports the lower extreme of inlet tube and closed inlet tube, is connected with a plurality of radiant tubes on the lateral wall of inlet tube, and the radiant tube is linked together with the wet return, has a plurality of bellyings on the outer wall of wet return, and the upper end of wet return is sealed, has the port at the lower extreme of wet return, and the port stretches out to jar external portion downwards, the seam welded seal of wet return and jar body.

Preferably, the tank further comprises an observation window, and the observation window is fixedly arranged at the top end of the tank body.

Preferably, the transmission case is further included, and the driven pulley and the driving pulley are both located in the transmission case.

Preferably, the radiation tube further comprises a wing plate and a support, wherein the wing plate is welded and fixed with the outer wall of the radiation tube, the support is fixedly connected to the inner wall of the tank body, and the wing plate is fixedly connected with the support.

Preferably, the water inlet pipe and the water return pipe are vertically arranged, and the radiant tube is horizontally arranged.

On the basis of the technical scheme, a feeding channel and a discharging channel are required to be arranged on the tank body from top to bottom respectively, wherein the position of the discharging channel is required to avoid the port at the lower end of the water return pipe, and a valve is required to be arranged on the discharging channel.

In the above technical scheme, the tank body is used for accommodating materials to be processed; the supporting legs are used for bearing the tank body; the bearing seat is used for bearing the bearing; the bearing is used for rotatably connecting the rotating shaft thereon; the rotating shaft is used for driving the homogenizing head to rotate; the driven belt pulley is in transmission with the driving belt pulley through a belt, and the driving belt pulley is driven by the motor to rotate so as to provide power for the rotation of the rotating shaft; the homogenizing head is of a conventional structure and is used for shearing and emulsifying the materials through rotary motion; the water inlet pipe is used for accessing refrigerant water; the refrigerant water flows through the water inlet pipe, the radiant tube and the water return pipe in sequence; the radiant tube is used for increasing the heat exchange area with the material; the water return pipe is used for returning the materials from the port; the bearing plate is used for bearing the water inlet pipe on one hand and sealing the lower port of the water inlet pipe on the other hand, so that the refrigerant must flow through the radiant tube; the outer wall of the water return pipe is provided with a protruding part for further increasing the heat exchange area.

In the preferred technical scheme, an observation window can be further added for observing the conditions in the tank body; a transmission case can be further added for accommodating and protecting the driving belt pulley and the driven belt pulley; and a wing plate and a bracket can be further added for bearing the radiant tube so as to ensure the structural stability of the radiant tube.

The utility model provides an emulsion machine water-cooling system. This technical scheme has abandoned the heat radiation structure of double-layered cover formula, places a part of refrigerant circulation pipeline in jar body in, has improved its specific configuration simultaneously. Specifically, the utility model discloses utilize the inlet tube to introduce refrigerant water, the inlet tube bottom adopts to bear the weight of the dish and play simultaneously and bear and seal the effect, and the inlet tube side sets up the horizontally radiant tube, both increases heat transfer area, spreads over each position in the jar body with the heat transfer surface again. The refrigerant flowing through the radiation pipe enters a water return pipe and finally flows back from the lower port; be equipped with the bellying on the wet return surface, help further increase heat transfer area. Meanwhile, the utility model discloses with the homogenizing head and the suitable side of actuating mechanism and move, can ensure that the refrigerant system can not influence its constitution. Use the utility model discloses, can make the heat-transfer face distribute around the heat production site, effectively increased heat transfer area simultaneously, have better radiating effect than conventional jacket structure.

Drawings

Fig. 1 is a schematic structural view of the whole of the present invention;

FIG. 2 is a schematic view of a partial structure of the rotating shaft according to the present invention;

FIG. 3 is a view showing the structure of the wing plate and the bracket;

in the figure:

1. tank body 2, supporting legs 3, bearing seat 4 and rotating shaft

5. Driven belt pulley 6, belt 7, driving belt pulley 8 and motor

9. Homogenizing head 10, water inlet pipe 11, bearing disc 12 and radiant tube

13. Return pipe 14, boss 15, port 16, observation window

17. A transmission case 18, a wing plate 19 and a bracket.

Detailed Description

The following will describe in detail specific embodiments of the present invention. Well-known structures or functions may not be described in detail in the following embodiments in order to avoid unnecessarily obscuring the details. Approximating language, as used herein in the following examples, may be applied to identify quantitative representations that could permissibly vary in number without resulting in a change in the basic function. Unless defined otherwise, technical and scientific terms used in the following examples have the same meaning as commonly understood by one of ordinary skill in the art to which this invention belongs.

Example 1

An emulsifying machine water-cooling heat dissipation system, as shown in fig. 1-3, comprises a tank body 1, supporting legs 2, a bearing seat 3, a rotating shaft 4, a driven belt pulley 5, a belt 6, a driving belt pulley 7, a motor 8, a homogenizing head 9, a water inlet pipe 10, a bearing disc 11, a radiation pipe 12, a water return pipe 13, a protruding part 14 and a port 15, wherein the supporting legs 2 are fixedly connected to the lower end of the tank body 1, the bearing seat 3 is fixedly connected to the upper end of the tank body 1, the rotating shaft 4 is arranged on the bearing seat 3 through a bearing, the rotating shaft 4 longitudinally extends into the tank body 1, the homogenizing head 9 is fixedly connected to the rotating shaft 4, and the homogenizing head 9 is positioned in; the top end of the rotating shaft 4 is fixedly connected with a driven belt pulley 5, the driven belt pulley 5 is in transmission connection with a driving belt pulley 7 through a belt 6, and the driving belt pulley 7 is in transmission connection with a main shaft of a motor 8; the inlet tube 10 vertically stretches into jar body 1 inside, fixedly connected with bears dish 11 on the inner wall of jar body 1, bear dish 11 and support inlet tube 10 and seal the lower extreme of inlet tube 10, be connected with a plurality of radiant tubes 12 on the lateral wall of inlet tube 10, radiant tube 12 is linked together with wet return 13, a plurality of bellyings 14 have on wet return 13's outer wall, wet return 13's upper end is sealed, lower extreme at wet return 13 has port 15, port 15 stretches out to jar body 1 outside downwards, wet return 13 and jar body 1's seam welded seal.

The device has the following structural characteristics: the tank body 1 is used for containing materials to be treated; the supporting legs 2 are used for bearing the tank body 1; the bearing seat 3 is used for bearing a bearing; the bearing is used for rotatably connecting the rotating shaft 4 thereon; the rotating shaft 4 is used for driving the homogenizing head 9 to rotate; the driven pulley 5 is in transmission with a driving pulley 7 through a belt 6, and the driving pulley 7 is driven by a motor 8 to rotate so as to provide power for the rotation of the rotating shaft 4; the homogenizing head 9 is of a conventional structure and is used for shearing and emulsifying the materials through rotary motion; the water inlet pipe 10 is used for accessing refrigerant water; the refrigerant water flows through the water inlet pipe 10, the radiant pipe 12 and the water return pipe 13 in sequence; the radiant tube 12 is used for increasing the heat exchange area with the material; the return pipe 13 is used for returning the materials from the port 15; the bearing disc 11 is used for bearing the water inlet pipe 10 on one hand and closing the lower port of the water inlet pipe 10 on the other hand, so that the refrigerant must flow through the radiant tube 12; the outer wall of the water return pipe 13 is provided with a convex part 14 for further increasing the heat exchange area.

Example 2

An emulsifying machine water-cooling heat dissipation system, as shown in fig. 1-3, comprises a tank body 1, supporting legs 2, a bearing seat 3, a rotating shaft 4, a driven belt pulley 5, a belt 6, a driving belt pulley 7, a motor 8, a homogenizing head 9, a water inlet pipe 10, a bearing disc 11, a radiation pipe 12, a water return pipe 13, a protruding part 14 and a port 15, wherein the supporting legs 2 are fixedly connected to the lower end of the tank body 1, the bearing seat 3 is fixedly connected to the upper end of the tank body 1, the rotating shaft 4 is arranged on the bearing seat 3 through a bearing, the rotating shaft 4 longitudinally extends into the tank body 1, the homogenizing head 9 is fixedly connected to the rotating shaft 4, and the homogenizing head 9 is positioned in; the top end of the rotating shaft 4 is fixedly connected with a driven belt pulley 5, the driven belt pulley 5 is in transmission connection with a driving belt pulley 7 through a belt 6, and the driving belt pulley 7 is in transmission connection with a main shaft of a motor 8; the inlet tube 10 vertically stretches into jar body 1 inside, fixedly connected with bears dish 11 on the inner wall of jar body 1, bear dish 11 and support inlet tube 10 and seal the lower extreme of inlet tube 10, be connected with a plurality of radiant tubes 12 on the lateral wall of inlet tube 10, radiant tube 12 is linked together with wet return 13, a plurality of bellyings 14 have on wet return 13's outer wall, wet return 13's upper end is sealed, lower extreme at wet return 13 has port 15, port 15 stretches out to jar body 1 outside downwards, wet return 13 and jar body 1's seam welded seal.

Meanwhile, the tank body comprises an observation window 16, wherein the observation window 16 is fixedly arranged at the top end of the tank body 1. The belt conveyor further comprises a transmission box 17, and the driven pulley 5 and the driving pulley 7 are both positioned in the transmission box 17. The tank also comprises a wing plate 18 and a bracket 19, wherein the wing plate 18 is welded and fixed with the outer wall of the radiant tube 12, the bracket 19 is fixedly connected on the inner wall of the tank body 1, and the wing plate 18 is fixedly connected with the bracket 19. The water inlet pipe 10 and the water return pipe 13 are vertically arranged, and the radiant pipe 12 is horizontally arranged.

In the technical scheme, an observation window 16 is further added for observing the condition in the tank body 1; a transmission case 17 is further added for accommodating and protecting the driving belt pulley 7 and the driven belt pulley 5; and a wing plate 18 and a bracket 19 are further added for bearing the radiant tube 12 so as to ensure the structural stability of the radiant tube 12.

The embodiments of the present invention have been described in detail, but the description is only for the preferred embodiments of the present invention, and is not intended to limit the present invention. Any modification, equivalent replacement, and improvement made within the scope of the present invention should be included in the protection scope of the present invention.

Claims (5)

1. The water-cooling heat dissipation system of the emulsifying machine is characterized by comprising a tank body (1), supporting legs (2), a bearing seat (3), a rotating shaft (4), a driven pulley (5), a belt (6), a driving pulley (7), a motor (8), a homogenizing head (9), a water inlet pipe (10), a bearing disc (11), a radiation pipe (12), a water return pipe (13), a protruding part (14) and a port (15), wherein the supporting legs (2) are fixedly connected to the lower end of the tank body (1), the bearing seat (3) is fixedly connected to the upper end of the tank body (1), the rotating shaft (4) is arranged on the bearing seat (3) through a bearing, the rotating shaft (4) longitudinally extends into the tank body (1), the homogenizing head (9) is fixedly connected to the rotating shaft (4), and the homogenizing head (9) is located inside the tank body (; the top end of the rotating shaft (4) is fixedly connected with a driven belt pulley (5), the driven belt pulley (5) is in transmission connection with a driving belt pulley (7) through a belt (6), and the driving belt pulley (7) is in transmission connection with a main shaft of a motor (8); inside inlet tube (10) vertically stretched into jar body (1), fixedly connected with bears dish (11) on the inner wall of jar body (1), bear dish (11) and support inlet tube (10) and seal the lower extreme of inlet tube (10), be connected with a plurality of radiant tubes (12) on the lateral wall of inlet tube (10), radiant tube (12) are linked together with wet return (13), a plurality of bellying (14) have on the outer wall of wet return (13), the upper end of wet return (13) is sealed, lower extreme at wet return (13) has port (15), port (15) stretch out downwards to jar body (1) outside, wet return (13) and the seam welded seal of jar body (1).

2. The water-cooling heat dissipation system of the emulsifying machine as claimed in claim 1, further comprising an observation window (16), wherein the observation window (16) is fixedly arranged at the top end of the tank body (1).

3. The water-cooling heat dissipation system of the emulsifying machine as claimed in claim 1, further comprising a transmission case (17), wherein the driven pulley (5) and the driving pulley (7) are both located in the transmission case (17).

4. The water-cooling heat dissipation system of the emulsifying machine as claimed in claim 1, further comprising a wing plate (18) and a bracket (19), wherein the wing plate (18) is welded and fixed with the outer wall of the radiant tube (12), the bracket (19) is fixedly connected with the inner wall of the tank body (1), and the wing plate (18) is fixedly connected with the bracket (19).

5. The water-cooling heat dissipation system of the emulsifying machine as claimed in claim 1, wherein the water inlet pipe (10) and the water return pipe (13) are arranged vertically, and the radiation pipe (12) is arranged horizontally.

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