CN216804144U - Quick cooling device of strip silica gel - Google Patents

Abstract

The utility model relates to a strip-shaped silica gel rapid cooling device which comprises a workbench with a transmission shaft support, a driving device comprising a servo motor, a main transmission shaft and a driving belt, a transmission device comprising first to third auxiliary transmission shafts and a mesh conveyor belt, a protective cover with a semi-closed structure, and a plurality of cold air guns comprising upper cold air guns and lower cold air guns. According to the utility model, due to the arrangement of the semi-closed structure protective cover, the upper and lower cold air discharge guns and the mesh conveyor belt, strip silica gel extruded by the gear pump on the production line can contact with enough cold quantity after entering the mesh conveyor belt, so that the strip silica gel is rapidly cooled to below 35 ℃, and a finished product obtains good quality.

Description

Quick cooling device of strip silica gel

Technical Field

The utility model relates to the technical field of rapid cooling of strip silica gel and other products on a production line, in particular to a strip silica gel rapid cooling device.

Background

In the production process of the silica gel, after the silica gel is filtered by a gear pump or a screw pump and extruded into strip silica gel, the temperature rises quickly and generally exceeds 60 ℃. Even with the use of a chilled water cooling system of significant effectiveness, the silica gel mass is over 40 ℃. However, because some custom-made silica gels are added with a vulcanizing agent, the reaction starts once the temperature exceeds 35 ℃, and the traditional cooling measures cannot meet the cooling requirement of the products, and finally the quality and the using effect of the finished products are influenced.

SUMMERY OF THE UTILITY MODEL

In order to overcome the above defects, the utility model provides a strip-shaped silica gel rapid cooling device which is convenient to install and simple to operate and can rapidly cool the product.

In order to achieve the above object, the present invention provides a strip silica gel rapid cooling device, which comprises:

a worktable on which a transmission shaft bracket is arranged;

the driving device comprises a servo motor, a main transmission shaft and a driving belt, wherein the servo motor is arranged on the workbench, the driving belt is used for connecting the servo motor and the main transmission shaft, and the main transmission shaft is rotatably arranged on the workbench;

a transmission device which comprises a first auxiliary transmission shaft, a second auxiliary transmission shaft, a third auxiliary transmission shaft and a mesh conveyor belt, wherein the first auxiliary transmission shaft and the second auxiliary transmission shaft are rotatably arranged on the transmission shaft bracket, the third auxiliary transmission shaft and the main transmission shaft face to face and are rotatably arranged on the workbench, and the mesh conveyor belt is arranged to be capable of sequentially transmitting the driving force of the main transmission shaft to the first auxiliary transmission shaft, the second auxiliary transmission shaft and the third auxiliary transmission shaft;

a shield installed on the table and configured as a semi-closed structure having both ends open;

and a plurality of cold air guns including an upper row of cold air guns blowing cold air toward the upper surface of the mesh-shaped conveyor belt and a lower row of cold air guns blowing cold air toward the lower surface of the mesh-shaped conveyor belt.

According to the utility model, due to the arrangement of the semi-closed structure protective cover, the upper and lower cold air discharging guns and the mesh conveyor belt, strip silica gel extruded by the gear pump on the production line can contact with enough cold energy after entering the mesh conveyor belt, so that the strip silica gel is rapidly cooled to below 35 ℃, and a finished product obtains good quality.

Furthermore, six upper cold air guns are arranged, and two lower cold air guns are arranged.

Through the arrangement, the cold air blown out by the cold air gun is quickly taken away from the surface of the strip-shaped silica gel through heat exchange in the process of passing the strip-shaped silica gel through the transmission device from the upper direction to the lower direction, so that the purpose of cooling is achieved.

Still further, the protection casing includes roof and two curb plates, and wherein, the roof constructs into the structure of the type of falling U that both ends board leaned out downwards, six go up the row of cold-blast rifle evenly distributed on this roof.

The arrangement mode enables the strip-shaped silica gel to be effectively cooled in the whole process of conveying on the mesh-shaped conveyor belt.

Further, two lower row cold air guns are disposed on one side plate of the shield or on the upper surface of the work table.

This arrangement enables the lower row of cooling air guns to blow air toward the bottom surface of the mesh conveyor belt, thereby cooling the product from the underside of the strip of silicone gum.

Still further, each air gun was connected via a tube to an external compressed air source of 0.5 MPa.

The cold air gun is connected with 0.5Mpa compressed air, and the compressed air can be converted into 0-4 ℃ strong cold air within 5 minutes when being sprayed out of the cold air gun.

And furthermore, the mesh-shaped conveying belt is arranged into a trapezoidal structure with a small upper part and a large lower part, and the first auxiliary transmission shaft and the second auxiliary transmission shaft are positioned at the upper end of the trapezoidal structure.

Through the structure, the strip-shaped silica gel runs along the trapezoidal transmission belt, and compared with the simple linear running, the path and time of running in the protective cover are increased, the contact time of the silica gel and cold air is prolonged, and the cooling effect is enhanced.

Still further, the mesh conveyor is a teflon conveyor having regular mesh openings.

Through the arrangement, the lower-row cooling air gun can effectively cool the product.

Preferably, the aperture of mesh sets up to 5mm or so, and such setting can guarantee the intensity and the support effect of conveyer belt, can maximize the assurance cooling effect again.

In addition, the driving device further comprises an active adjustment controller, and the active adjustment controller is installed on the workbench and electrically connected with the servo motor.

Through the setting, make can operate initiative adjustment control ware, drive the servo motor operation, and then drive belt, drive final drive shaft, drive three counter drive shaft, and then drive netted conveyer belt and convey the strip material, can control the transfer rate of material on netted conveyer belt simultaneously, with the automatic film machine functioning speed phase-match of rear end connection on the whole silica gel production line.

Still further, be provided with inside lining soundproof cotton on the safety guard.

Through the arrangement, the noise of the protective cover can be reduced while cold air is effectively kept.

These and other aspects of the utility model are apparent from and will be elucidated with reference to the embodiments described hereinafter.

Drawings

The structure and further objects and advantages of the present invention will be better understood by the following description taken in conjunction with the accompanying drawings, in which like reference characters identify like elements, and in which:

FIG. 1 is a perspective view of a device for rapidly cooling silica gel in strip form according to an embodiment of the present invention;

FIG. 2 is a schematic perspective view of the strip silica gel rapid cooling device shown in FIG. 1 at another angle;

FIG. 3 is a perspective view of the strip-shaped silica gel rapid cooling device shown in FIG. 1 after the protective cover is removed;

fig. 4 is a schematic plan elevation view of the strip-shaped silica gel rapid cooling device shown in fig. 1 after half of the protective cover is cut away.

Detailed Description

Embodiments of the present invention will be described below with reference to the accompanying drawings.

In this document, the directions used to explain the structure and/or actions of the various parts of the disclosed embodiments, such as "upper", "lower", "front", "rear", etc., are not absolute, but relative. These representations are suitable when the various parts of the disclosed embodiments are located in the positions shown in the figures, and if the position or frame of reference of the disclosed embodiments is changed, they are also changed according to the change in the position or frame of reference of the disclosed embodiments.

The term "strip silica gel" as used herein includes strip silica gel in a narrow sense and other products having a similar shape or similar cooling requirements as strip silica gel.

As shown in fig. 1 to 4, the device for rapidly cooling a strip of silicone gel according to an embodiment of the present invention includes a table 1 on which a transmission shaft support 10 is mounted, a driving device, a transmission device, a protective cover 7, and a plurality of air cooling guns 9.

As shown in fig. 4, and referring to fig. 1 and 3, the driving means includes a servo motor 31 mounted on the table 1, a main drive shaft 33, and a drive belt 35 connecting the servo motor 31 and the main drive shaft 33, the main drive shaft 32 being rotatably mounted on the table 30; the transmission means comprises a first counter-drive shaft 51, a second counter-drive shaft 52, a third counter-drive shaft 53 and a mesh conveyor belt 54. Wherein, the first sub-transmission shaft 51 and the second sub-transmission shaft 52 are rotatably installed on the transmission shaft bracket 10; the third counter drive shaft 53 is arranged face to face with the main drive shaft 33 and is rotatably mounted on the table 1; the mesh belt 54 is arranged to transmit the driving force of the main transmission shaft 33 to the first sub-transmission shaft 51, the second sub-transmission shaft 52, and the third sub-transmission shaft 53 in this order.

It should be understood that the drive means further comprise an active adjustment control 30, which active adjustment control 30 is mounted on the table 1 and is electrically connected to a servo motor 31. By operating the active adjustment controller 30, the operation of the servo motor 31 can be controlled to drive the driving belt 35 and further the main transmission shaft 33, and to transmit power to the three auxiliary transmission shafts, and further to drive the mesh conveyor belt 54 to convey the strip-shaped material thereon.

As shown in fig. 1, 2, and 4, in the present embodiment, the protection cover 7 is mounted on the table 1 and is configured as a semi-closed structure open at both ends. In the present embodiment, the hood 7 includes a top plate 70 and two side plates, i.e., a front side plate 71 and a rear side plate 72, wherein the top plate 70 is configured in an inverted U-shaped structure, and two end plates 701 of the inverted U-shaped structure are disposed to be inclined downward and outward. In addition, the protective cover 7 is provided with lining soundproof cotton (not shown), so that the protective cover 7 can effectively keep cold wind and reduce noise.

As shown in fig. 1 to 4, the plurality of air-cooling guns 9 are divided into an upper row of air-cooling guns blowing cold air toward the upper surface of the mesh conveyor 54 and a lower row of air-cooling guns blowing cold air toward the lower surface of the mesh conveyor 54. Wherein, the number of the upper row of cold air guns is six, and the number of the lower row of cold air guns is two. In the present embodiment, six upper rows of cold air guns are uniformly arranged on the top plate 70 of the protective cover, specifically, two cold air guns are arranged on the bottom plate 702 of the inverted U-shaped structure, and the other four cold air guns are arranged two by two on the two end plates 701 of the inverted U-shaped structure; two lower rows of the air guns are arranged on the rear side plate 72 of the hood 7. It should be understood that in other embodiments, two lower rows of cooling air guns may be disposed on the upper surface of the table 1. In addition, in the present embodiment, each of the air guns is connected to an external compressed air source (not shown) of 0.5Mpa via a pipe (not shown).

As shown in fig. 3, and referring to fig. 1 and 2, the mesh conveyor belt 54 is arranged in a trapezoidal structure having a small top and a large bottom, the first and second sub-transmission shafts 51 and 52 are located at an upper end of the trapezoidal structure, and the third sub-transmission shaft 53 and the main transmission shaft 33 are located at a lower end of the trapezoidal structure. Of course, in other embodiments, the mesh conveyor belt 54 may be arranged in other shapes as long as the running route of the mesh conveyor belt 54 in the protective cover 7 can be extended, because the extension of the running route can help to increase the contact time of the strip-shaped silica gel with the cold air, thereby enhancing the cooling effect of the product.

As further shown in fig. 3, the mesh conveyor belt 54 is a teflon conveyor belt having regular meshes, and the mesh size is preferably set to about 5mm by 5mm, which can ensure both the strength and the supporting effect of the conveyor belt and the cooling effect to the maximum.

While the utility model has been described with respect to the foregoing technical disclosure and features, it will be understood that various changes and modifications in the above structure, including combinations of features disclosed herein either individually or as claimed, and obviously including other combinations of such features, may be resorted to by those skilled in the art, without departing from the spirit of the utility model. Such variations and/or combinations are within the skill of the art to which the utility model pertains and are within the scope of the following claims.

Claims (10)

1. A quick cooling device of strip silica gel, its characterized in that includes:

a worktable on which a transmission shaft bracket is arranged;

the driving device comprises a servo motor, a main transmission shaft and a driving belt, wherein the servo motor is arranged on the workbench, the driving belt is used for connecting the servo motor and the main transmission shaft, and the main transmission shaft is rotatably arranged on the workbench;

a transmission device which comprises a first auxiliary transmission shaft, a second auxiliary transmission shaft, a third auxiliary transmission shaft and a mesh conveyor belt, wherein the first auxiliary transmission shaft and the second auxiliary transmission shaft are rotatably arranged on the transmission shaft bracket, the third auxiliary transmission shaft and the main transmission shaft face to face and are rotatably arranged on the workbench, and the mesh conveyor belt is arranged to be capable of sequentially transmitting the driving force of the main transmission shaft to the first auxiliary transmission shaft, the second auxiliary transmission shaft and the third auxiliary transmission shaft;

a shield installed on the table and configured as a semi-closed structure having both ends open;

and a plurality of cold air guns including an upper row of cold air guns blowing cold air toward the upper surface of the mesh-shaped conveyor belt and a lower row of cold air guns blowing cold air toward the lower surface of the mesh-shaped conveyor belt.

2. The device for rapidly cooling silica gel in strip form as claimed in claim 1, wherein the number of the upper row of the cooling air blowing guns is six, and the number of the lower row of the cooling air blowing guns is two.

3. The device for rapidly cooling silica gel in strip form as claimed in claim 2, wherein the protective cover comprises a top plate and two side plates, wherein the top plate is configured into an inverted U-shaped structure with two end plates inclining downwards and outwards, and six upper rows of cooling air guns are uniformly distributed on the top plate.

4. A strip silica gel rapid cooling device as claimed in claim 3, wherein two lower row of cooling air guns are disposed on one of the side plates of the protection cover or on the upper surface of the working table.

5. A rapid cooling device for silicone strip as claimed in claim 1, wherein each of said plurality of air cooling guns is connected via a tube to an external compressed air source of 0.5 Mpa.

6. A device for rapidly cooling silica gel strip as claimed in any one of claims 1 to 5, wherein said mesh conveyor is arranged in a trapezoidal structure with a smaller top and a larger bottom, and said first counter-drive shaft and said second counter-drive shaft are located at the upper end of said trapezoidal structure.

7. The device for rapidly cooling silica gel strip as claimed in claim 6, wherein the mesh conveyor belt is a Teflon conveyor belt with regular mesh.

8. The device for rapidly cooling silica gel in strip form as claimed in claim 7, wherein the mesh openings are set at 5mm by 5 mm.

9. The device for rapidly cooling silica gel strip as claimed in claim 6, wherein the driving device further comprises an active adjustment controller, and the active adjustment controller is mounted on the worktable and electrically connected to the servo motor.

10. A strip silica gel rapid cooling device as claimed in any one of claims 1 to 5, wherein the protective cover is provided with an inner lining soundproof cotton.

Images