CN216182146U - A calendering cooling device for geomembrane production - Google Patents

Abstract

The utility model discloses a calendering and cooling device for geomembrane production, which comprises an equipment body, wherein a forming device for geomembrane forming is arranged in the equipment body, and a cooling device is arranged at a position, close to one side of the forming device, in the equipment body. According to the utility model, the transmission connection of the adjacent ventilation pipes is realized by arranging the ventilation pipes and the gear rings which can rotate, the reciprocating movement of wind direction is realized by arranging the air outlet pipes, the geomembrane can be fully covered, the cooling effect of the edge of the geomembrane is ensured, and the cooling effect of air is improved by arranging the condensate pipes.

Description

A calendering cooling device for geomembrane production

Technical Field

The utility model relates to a cooling device, in particular to a calendering cooling device for geomembrane production, and belongs to the technical field of geomembrane production.

Background

The geomembrane after being rolled in the production process of the geomembrane needs to be subjected to cooling treatment so as to shape the geomembrane and facilitate subsequent winding into a roll shape.

But the existing cooling mode adopts an air cooling mode to directly blow the geomembrane to cool the geomembrane, an air outlet is fixed, and the cooling effect is not ideal enough.

SUMMERY OF THE UTILITY MODEL

The utility model aims to overcome the defects in the prior art and provide a calendering and cooling device for geomembrane production.

In order to solve the problems, the utility model adopts the following technical scheme: a calendering cooling device for producing geomembranes comprises an equipment body, wherein a forming device for forming the geomembrane is arranged in the equipment body, a cooling device is arranged in the equipment body and close to one side of the forming device, the cooling device comprises a plurality of ventilation pipes arranged in the equipment body, the ventilation pipes are uniformly arranged at intervals along the moving direction of the geomembrane, one end of each ventilation pipe is a closed end, the other end of each ventilation pipe penetrates out of one side of the equipment body, the two ends of each ventilation pipe are respectively and rotatably connected with the two side walls of the equipment body through bearing seats, the lower end of each ventilation pipe is respectively provided with a plurality of air outlet pipes, the air outlet pipes are uniformly arranged at intervals along the length direction of the ventilation pipes, air in the ventilation pipes is blown to the geomembrane through the air outlet pipes, and a gear ring is coaxially and fixedly arranged at the position, close to the inner wall of the equipment body, on each ventilation pipe, two gear rings on two adjacent ventilation pipes are connected in a meshed mode, a swing rod is fixedly mounted on one side of one ventilation pipe, the swing rod is driven by an electric telescopic rod to swing up and down, one end, extending out of the equipment body, of each ventilation pipe is communicated with a fan through a pipeline unit, and an air cooling unit is arranged at one end, far away from the pipeline unit, of the fan.

The following is a further optimization of the present invention to the above scheme: the pipeline unit comprises a conical cylinder connected with the air outlet of the fan in a sealing mode, one end, far away from the fan, of the conical cylinder is communicated with an air outlet main pipe, and the fan and the air outlet main pipe are connected with the equipment body respectively.

Further optimization: one side that the air-out was responsible for is connected with a plurality of branch pipes, and this a plurality of branch pipes interval certain distance evenly sets up.

Further optimization: the branch pipes are respectively communicated with the ventilation pipes through rotary joints.

Further optimization: and the air outlet pipes on the two adjacent ventilation pipes are arranged in a staggered manner.

Further optimization: the air outlet pipe is of an integrally connected two-section structure, one section is a cylinder communicated with the ventilation pipe, the other section is a fan-shaped plate, a fan-shaped cavity communicated with the cylinder is formed in the fan-shaped plate, and the cavity penetrates through one end face of the air outlet pipe and forms an arc-shaped air outlet.

Further optimization: the length direction of the air outlet is arranged along the length direction of the ventilation pipe.

Further optimization: the air cooling unit comprises an air inlet pipeline, one end of the air inlet pipeline is communicated with one end of the fan, a filter screen is arranged at the other end of the air inlet pipeline, a condensate pipe which is arranged in an S shape is arranged in the air inlet pipeline, and the condensate pipe is connected with a condensate water pool through a circulating pump.

Further optimization: the air inlet pipeline is internally provided with two spoilers close to one end of the fan, and the spoilers are arranged in a vertically staggered manner.

During the use, outside gas gets into in the intake stack and gets into in the ventilation pipe after the cooling, then blows to the geomembrane through the air outlet, and electric telescopic handle drives the swinging arms swing simultaneously, and then the ventilation pipe drives out the reciprocal swing of tuber pipe.

According to the utility model, the transmission connection of the adjacent ventilation pipes is realized by arranging the ventilation pipes and the gear rings which can rotate, the reciprocating movement of wind direction is realized by arranging the air outlet pipes, the geomembrane can be fully covered, the cooling effect of the edge of the geomembrane is ensured, and the cooling effect of air is improved by arranging the condensate pipes.

The utility model is further illustrated with reference to the following figures and examples.

Drawings

FIG. 1 is a schematic structural diagram of an embodiment of the present invention;

FIG. 2 is a top view of an auxiliary cooling unit according to an embodiment of the present invention;

fig. 3 is a schematic structural view of an air outlet pipe in the embodiment of the present invention.

In the figure: 1-an equipment body; 2-a forming device; 3-gear ring; 4-a ventilation pipe; 5-air outlet pipe; 6-a swing lever; 7-an electric telescopic rod; 8-air outlet; 9-air outlet main pipe; 10-branch pipe; 11-a rotary joint; 12-a cone; 13-a fan; 14-a spoiler; 15-an air inlet pipeline; 16-condensate pipe.

Detailed Description

In the embodiment, as shown in fig. 1 to 3, a calendering and cooling device for geomembrane production comprises an equipment body 1, wherein a forming device 2 for geomembrane forming is arranged in the equipment body 1 at a position close to one end, and a cooling device is arranged in the equipment body 1 at a position close to one side of the forming device 2.

The cooling device comprises a plurality of ventilation pipes 4 arranged in the equipment body 1, and the axes of the ventilation pipes 4 are vertical to the moving direction of the geomembrane.

A plurality of ventilation pipes 4 evenly set up along the trend of geomembrane at a certain distance interval, and the one end of every ventilation pipe 4 is the blind end, and the other end runs through outside the one side of equipment body 1, and sets up the hole that holds ventilation pipe 4 one end and pass on the equipment body 1.

The two ends of the vent pipe 4 are respectively connected with the two side walls of the equipment body 1 through bearing seats in a rotating mode, so that the vent pipe 4 can rotate conveniently.

The lower extreme of every ventilation pipe 4 is fixed mounting respectively has a plurality of play tuber pipes 5, and a plurality of play tuber pipes 5 evenly set up along the length direction interval certain distance of ventilation pipe 4, and the ventilation pipe 4 interior gas blows to the geomembrane through going out tuber pipe 5.

Gear rings 3 are coaxially and fixedly mounted on the positions, close to the inner wall of the equipment body 1, of the ventilation pipes 4, the two gear rings 3 on the two adjacent ventilation pipes 4 are connected in a meshed mode, and one ventilation pipe 4 rotates to drive the other ventilation pipe 4 to rotate in the reverse direction.

And a swing rod 6 is fixedly installed on one side of one ventilation pipe 4 positioned on the edge, and the swing rod 6 is driven by an electric telescopic rod 7 to swing up and down so as to drive the ventilation pipe 4 to rotate and drive a gear ring 3 on the ventilation pipe to rotate.

The telescopic end of the electric telescopic rod 7 is hinged with one end of the oscillating rod 6, and the other end of the electric telescopic rod is hinged with the inner wall of the equipment body 1.

One end of each ventilation pipe 4 extending out of the equipment body 1 is communicated with a fan 13 through a pipeline unit, and the fan 13 sends wind into the ventilation pipes 4 through the pipeline unit.

And an air cooling unit is arranged at one end of the fan 13, which is far away from the pipeline unit, and is used for cooling air entering the fan 13.

The pipeline unit comprises a conical cylinder 12 connected with an air outlet of a fan 13 in a sealing mode, one end, far away from the fan 13, of the conical cylinder 12 is communicated with an air outlet main pipe 9, and the fan 13 and the air outlet main pipe 9 are connected with the equipment body 1 respectively.

One side of the air outlet main pipe 9 is connected with a plurality of branch pipes 10, and the plurality of branch pipes 10 are evenly arranged at certain intervals.

The branch pipes 10 are respectively communicated with the ventilation pipes 4 through the rotary joints 11, so that the design is convenient for the wind in the wind outlet main pipe 9 to enter the ventilation pipes 4 through the branch pipes 10 and the rotary joints 11.

The air outlet pipes 5 on the two adjacent ventilation pipes 4 are arranged in a staggered mode, so that the cooling uniformity is improved.

The air outlet pipe 5 is of an integrally connected two-section structure, one section is a cylinder communicated with the ventilation pipe 4, the other section is a fan-shaped plate, a fan-shaped cavity communicated with the cylinder is formed in the fan-shaped plate, the cavity penetrates through one end face of the air outlet pipe 5 and forms an arc-shaped air outlet 8, and therefore the design can blow out air in a fan shape, and the full coverage of the geomembrane in the width direction is guaranteed.

The length direction of the air outlet 8 is arranged along the length direction of the ventilation pipe 4, so that the geomembrane can be completely covered in the width direction.

The air cooling unit comprises an air inlet pipeline 15 with a circular ring-shaped cross section, and the air inlet pipeline 15 is fixedly installed on one side of the equipment body 1.

One end of the air inlet pipeline 15 is communicated with one end of the fan 13, a filter screen is arranged at the other end of the air inlet pipeline, a condensate pipe 16 which is arranged in an S shape is arranged in the air inlet pipeline 15, and the condensate pipe 16 is connected with a condensate water pool through a circulating pump.

A spoiler 14 is fixedly installed in the air inlet pipe 15 at a position close to one end of the fan 13, and the longitudinal section of the spoiler 14 is fan-shaped and is obliquely arranged in the air inlet pipe 15.

The spoilers 14 are arranged in two and are arranged in a vertically staggered manner, so that the air flow cooling effect is improved.

During the use, outside gas gets into in the intake stack 15 and gets into in the ventilation pipe 4 after the cooling, then blows to the geomembrane through air outlet 8, and electric telescopic handle 7 drives the swing arm 6 swing simultaneously, and then ventilation pipe 4 drives out the reciprocal swing of tuber pipe 5.

According to the utility model, the transmission connection of the adjacent ventilation pipes is realized by arranging the ventilation pipes and the gear rings which can rotate, the reciprocating movement of wind direction is realized by arranging the air outlet pipes, the geomembrane can be fully covered, the cooling effect of the edge of the geomembrane is ensured, and the cooling effect of air is improved by arranging the condensate pipes.

Claims (9)

1. A calendering cooling device for geomembrane production which characterized in that: the device comprises a device body (1), a forming device (2) for forming the geomembrane is arranged in the device body (1), a cooling device is arranged in the device body (1) and close to one side of the forming device (2), the cooling device comprises a plurality of ventilation pipes (4) arranged in the device body (1), the ventilation pipes (4) are uniformly arranged along the moving direction of the geomembrane at intervals, one end of each ventilation pipe (4) is a closed end, the other end of each ventilation pipe penetrates out of one side of the device body (1), two ends of each ventilation pipe (4) are respectively and rotatably connected with two side walls of the device body (1) through bearing seats, a plurality of air outlet pipes (5) are respectively arranged at the lower end of each ventilation pipe (4), the air outlet pipes (5) are uniformly arranged along the length direction of the ventilation pipes (4) at intervals, gas in the ventilation pipes (4) is blown to the geomembrane through the air outlet pipes (5), the coaxial fixed mounting in position that is close to equipment body (1) inner wall has ring gear (3) on every ventilation pipe (4), two ring gear (3) meshing on two adjacent ventilation pipe (4) are connected, one side fixed mounting of one of them ventilation pipe (4) has swinging arms (6), swinging arms (6) are driven the luffing motion by electric telescopic handle (7), the outer one end of stretching out equipment body (1) on every ventilation pipe (4) is passed through pipeline unit and fan (13) intercommunication, the one end of keeping away from pipeline unit on fan (13) is provided with air cooling unit.

2. The calendering cooling device for geomembrane production according to claim 1, wherein: the pipeline unit comprises a conical cylinder (12) connected with an air outlet of the fan (13) in a sealing mode, one end, far away from the fan (13), of the conical cylinder (12) is communicated with an air outlet main pipe (9), and the fan (13) and the air outlet main pipe (9) are connected with the equipment body (1) respectively.

3. A calendering cooling apparatus for geomembrane production according to claim 2, wherein: one side of the air outlet main pipe (9) is connected with a plurality of branch pipes (10), and the branch pipes (10) are evenly arranged at intervals.

4. A calendering cooling apparatus for geomembrane production according to claim 3, wherein: the branch pipes (10) are respectively communicated with the ventilation pipes (4) through rotary joints (11).

5. The calendering cooling device for geomembrane production according to claim 4, wherein: the air outlet pipes (5) on the two adjacent ventilation pipes (4) are arranged in a staggered manner.

6. The calendering cooling device for geomembrane production according to claim 5, wherein: the air outlet pipe (5) is of an integrally connected two-section structure, one section is a cylinder communicated with the ventilation pipe (4), the other section is a fan-shaped plate, a fan-shaped cavity communicated with the cylinder is formed in the fan-shaped plate, and the cavity penetrates through one end face of the air outlet pipe (5) and forms an arc-shaped air outlet (8).

7. The calendering cooling device for geomembrane production according to claim 6, wherein: the length direction of the air outlet (8) is arranged along the length direction of the ventilation pipe (4).

8. A calendering cooling apparatus for geomembrane production according to claim 7, wherein: the air cooling unit comprises an air inlet pipeline (15), one end of the air inlet pipeline (15) is communicated with one end of the fan (13), a filter screen is arranged at the other end of the air inlet pipeline, a condensate pipe (16) which is arranged in an S shape is arranged in the air inlet pipeline (15), and the condensate pipe (16) is connected with a condensate water pool through a circulating pump.

9. A calendering cooling apparatus for geomembrane production according to claim 8, wherein: the air inlet pipeline (15) is internally provided with two spoilers (14) at positions close to one end of the fan (13), and the spoilers (14) are arranged in a vertically staggered manner.

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