CN214725745U - Design cooling device is used in cotton production of irradiation crosslinked polyethylene bubble - Google Patents

Abstract

The utility model discloses a cotton production of irradiation crosslinked polyethylene bubble is with design cooling device relates to the cotton technical field of irradiation crosslinked polyethylene bubble, for when solving the cotton production of current irradiation crosslinked polyethylene bubble, because dry cooling efficiency is low simultaneously, causes the cotton lower problem of design productivity of irradiation crosslinked polyethylene bubble. The front end of the cooling shell is provided with a front door plate, the front end of the front door plate is provided with monitoring glass, the lower end of the monitoring glass is provided with a door handle, the two sides of the cooling shell are provided with feeding boxes, the lower end of each feeding box is provided with a cooling fan, the lower end of each cooling fan is provided with a discharge hole, the two sides of the inside of the cooling shell are provided with first conveying belts, each conveying belt is provided with a blowing spray pipe above, an air suction table is arranged below each first conveying belt, and the inner wall of each feeding box is provided with a dustproof strip.

Description

Design cooling device is used in cotton production of irradiation crosslinked polyethylene bubble

Technical Field

The utility model relates to a cotton technical field of irradiation crosslinked polyethylene bubble specifically is a cotton production of irradiation crosslinked polyethylene bubble is with design cooling device.

Background

In conventional coil steel saddles, such as application number 201921175977.1; the name is cooling equipment for producing electronic cross-linked polyethylene foam. The device includes: the base, the top of base fixed mounting respectively has the cotton production facility of bubble and returns the shaped plate, and returns the shaped plate and lie in one side of the cotton production facility of bubble, the utility model discloses the practicality is strong, and the gaseous row after will cooling is put into the serpentine pipe to this can realize cooling down the bubble cotton, makes the bubble cotton after production is accomplished, cooling that can be rapid, and the cotton inlayer structure rapid shaping of bubble of being convenient for has effectually strengthened the cotton toughness and the elasticity of bubble, and it is long when accelerating the cotton production of bubble greatly to have accelerated the cotton cooling rate of bubble simultaneously, with this effectual improvement bubble cotton production efficiency.

However, when the existing irradiation crosslinking polyethylene foam is produced, the problem of low shaping productivity of the irradiation crosslinking polyethylene foam is caused because the drying and cooling efficiency is low at the same time; therefore, the existing requirements are not met, and a shaping cooling device for producing the irradiation crosslinking polyethylene foam is provided for the requirement.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to provide a cotton production of irradiation crosslinked polyethylene bubble is with design cooling device to when solving the cotton production of the current irradiation crosslinked polyethylene bubble that provides in the above-mentioned background art, because dry cooling efficiency is low simultaneously, cause the cotton lower problem of design productivity of irradiation crosslinked polyethylene bubble.

In order to achieve the above object, the utility model provides a following technical scheme: a shaping and cooling device for producing irradiation cross-linked polyethylene foam comprises a cooling shell, wherein a front door plate is arranged at the front end of the cooling shell and is connected with a rotating shaft of the cooling shell, monitoring glass is arranged at the front end of the front door plate, a door handle is arranged at the lower end of the monitoring glass, feeding boxes are arranged on two sides of the cooling shell and are welded with the cooling shell, a cooling fan is arranged at the lower end of each feeding box and is welded with the cooling shell, a discharge port is arranged at the lower end of each cooling fan and is integrally formed with the cooling shell, two first conveying belts are arranged on two inner sides of the cooling shell and are fixedly connected with bolts on the inner wall of the cooling shell, and a blowing spray pipe is arranged above each first conveying belt, and the blowing spray pipe is connected with a cooling fan pipeline, an air suction table is arranged below each first conveying belt and is connected with the cooling fan pipeline, and each dustproof strip is arranged on the inner wall of the feeding box and is fixedly connected with the inner wall of the feeding box through bolts.

Preferably, a merging pipe is arranged between the two first conveyor belts, a heating pipe is arranged at the lower end of the merging pipe, and the heating pipe is fixedly connected with the inner wall of the cooling shell through bolts.

Preferably, the lower end of the heating pipe is provided with a material distribution partition plate, the material distribution partition plate is connected with the heating pipe in a welding mode, the two sides of the lower portion of the material distribution partition plate are provided with second conveying belts, and the second conveying belts are fixedly connected with bolts on the inner wall of the cooling shell.

Preferably, the inner wall of the heating pipe is provided with an electric heating ring, the electric heating ring is connected with the inner wall of the material distribution partition plate in a welding mode, the inner wall of the electric heating ring is provided with a material distribution inner plate, and the material distribution inner plate is connected with the inner wall of the electric heating ring in a welding mode.

Preferably, the upper end of each air suction table is provided with an air suction port, and the air suction ports are connected with the air suction tables in a welding mode.

Preferably, the lower end of each blowing spray pipe is provided with a nozzle, the lower end of each nozzle is provided with a net-shaped spray head, and the net-shaped spray heads are connected with the nozzles in a welded mode.

Compared with the prior art, the beneficial effects of the utility model are that:

1. the utility model discloses a cooling blower, the platform of breathing in, first conveyer belt, the setting of the spray tube of blowing, will need refrigerated bubble cotton to drop into from feed box department earlier, later by the transportation of first conveyer belt, in the transportation on first conveyer belt, cooling blower starts, the air current that cooling blower produced is along the induction port, the platform of breathing in, cooling blower, at last from blowing nozzle discharge on the spray tube, the combustion gas stream carries out the forced air cooling to the bubble cotton, and the low atmospheric pressure air current of induction port department makes the bubble cotton can adsorb on first conveyer belt, prevent that the bubble cotton from being blown, make the bubble cotton can fully the forced air cooling design.

2. Through the merging tube, the heating pipe, divide the setting of material baffle, after the bubble is cotton through first conveyer belt forced air cooling, along with first conveyer belt transport, transport it to the merging tube, the merging tube is collected the bubble cotton of both sides simultaneously and is moved down, the bubble is cotton through the heating pipe, do drying process for the bubble cotton of process by the electric heating coil of heating pipe inside, make the bubble cotton can be after the design quick drying, later fall on the natural drying transports on respective second conveyer belt from dividing the material baffle, two drying lines of device can dry the bubble cotton simultaneously, device design efficiency has greatly been improved, when having solved current irradiation crosslinking polyethylene bubble cotton production, because dry cooling efficiency is low simultaneously, cause the lower problem of irradiation crosslinking polyethylene bubble cotton design productivity.

Drawings

Fig. 1 is a schematic view of the overall structure of the present invention;

FIG. 2 is a schematic view of the internal structure of the present invention;

FIG. 3 is a schematic view of the top view of the material separating partition plate of the present invention;

in the figure: 1. cooling the housing; 2. a front door panel; 3. monitoring the glass; 4. a door handle; 5. a feeding box; 6. a cooling fan; 7. a discharge port; 8. a first conveyor belt; 9. a blowing nozzle; 10. a nozzle; 11. a mesh-shaped spray head; 12. a suction table; 13. an air suction port; 14. merging the pipes; 15. heating a tube; 16. a material distributing clapboard; 17. a second conveyor belt; 18. a dust-proof strip; 19. an electric heating coil; 20. divide the material inner panel.

Detailed Description

The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments.

Referring to fig. 1-3, the present invention provides an embodiment: a shaping and cooling device for producing irradiation cross-linked polyethylene foam comprises a cooling shell 1, wherein a front door plate 2 is arranged at the front end of the cooling shell 1, the front door plate 2 is connected with the cooling shell 1 in a rotating mode, monitoring glass 3 is arranged at the front end of the front door plate 2, a door handle 4 is arranged at the lower end of the monitoring glass 3, feeding boxes 5 are arranged on two sides of the cooling shell 1, the feeding boxes 5 are connected with the cooling shell 1 in a welding mode, a cooling fan 6 is arranged at the lower end of each feeding box 5, the cooling fan 6 is connected with the cooling shell 1 in a welding mode, a discharging port 7 is arranged at the lower end of each cooling fan 6, the discharging port 7 and the cooling shell 1 are arranged in an integrated mode, first conveying belts 8 are arranged on two sides inside the cooling shell 1, the first conveying belts 8 are fixedly connected with bolts on the inner wall of the cooling shell 1, and a blowing spray pipe 9 is arranged above each first conveying belt 8, and the blowing spray pipe 9 is connected with the cooling fan 6 through a pipeline, the air suction table 12 is arranged below each first conveying belt 8, the air suction table 12 is connected with the cooling fan 6 through a pipeline, the inner wall of each feeding box 5 is provided with a dustproof strip 18, and the dustproof strips 18 are fixedly connected with the inner wall of the feeding box 5 through bolts.

Further, a combining pipe 14 is arranged between the two first conveyor belts 8, a heating pipe 15 is arranged at the lower end of the combining pipe 14, the heating pipe 15 is fixedly connected with the inner wall of the cooling shell 1 through bolts, and the combining pipe 14 conveys the foam guided in the two sides to the heating pipe 15 for drying treatment, so that the production cost of the device is reduced, and the energy loss is reduced.

Further, the lower extreme of heating pipe 15 is provided with divides material baffle 16, and divides material baffle 16 and heating pipe 15 welded connection, divides the below both sides of material baffle 16 and all is provided with second conveyer belt 17, and second conveyer belt 17 and cooling housing 1 inner wall bolt fixed connection, divides material baffle 16 to derive the bubble cotton of both sides respectively to second conveyer belt 17 on, carries out natural drying, has greatly utilized the limited space of device, improves the design yields.

Further, an electric heating ring 19 is arranged on the inner wall of the heating pipe 15, the electric heating ring 19 is connected with the inner wall of the material separating partition plate 16 in a welding mode, a material separating inner plate 20 is arranged on the inner wall of the electric heating ring 19, the material separating inner plate 20 is connected with the inner wall of the electric heating ring 19 in a welding mode, and the electric heating ring 19 accelerates the drying treatment of the foam.

Further, every upper end of inhaling platform 12 all is provided with induction port 13, and induction port 13 and 12 welded connection of inhaling, and induction port 13 department forms the negative pressure because cooling fan 6's effect for bubble cotton on the first conveyer belt 8 can be adsorbed on first conveyer belt 8, prevents that the air current from blowing away the bubble cotton.

Further, the lower extreme of every spray tube 9 of blowing all is provided with nozzle 10, and the lower extreme of nozzle 10 is provided with netted shower nozzle 11, and netted shower nozzle 11 and nozzle 10 welded connection, and netted shower nozzle 11 makes the air current dispersion that blows out, prevents that high-speed air current from carrying out direct impact and blowing off the cotton influence processing of bubble to the bubble.

The working principle is as follows: when the device is used, foam to be cooled is firstly put in from the feeding box 5 and then is transported by the first conveyor belt 8, the cooling fan 6 is started while being transported on the first conveyor belt 8, air flow generated by the cooling fan 6 is exhausted from the nozzle 10 on the blowing nozzle 9 along the air suction port 13, the air suction table 12 and the cooling fan 6, air cooling is carried out on the foam by the exhausted air flow, the foam can be adsorbed on the first conveyor belt 8 by the low-pressure air flow at the air suction port 13, the foam is prevented from being blown, the foam can be fully air-cooled and shaped, after the foam is air-cooled by the first conveyor belt 8, the foam is conveyed to the merging pipe 14 along with the first conveyor belt 8 and is collected and moved downwards by the merging pipe 14, the foam passes through the heating pipe 15, the electric heating ring 19 in the heating pipe 15 is used for drying the passing foam, and the foam can be rapidly dried after being shaped, then fall on respective second conveyer belt 17 from dividing material baffle 16 and carry out the natural drying and transport out, two drying lines of device can dry the bubble cotton simultaneously, have greatly improved device design efficiency, have solved when current irradiation crosslinked polyethylene bubble cotton production, because dry cooling efficiency is low simultaneously, cause the problem that irradiation crosslinked polyethylene bubble cotton design productivity is lower.

It is obvious to a person skilled in the art that the invention is not restricted to details of the above-described exemplary embodiments, but that it can be implemented in other specific forms without departing from the spirit or essential characteristics of the invention. The present embodiments are therefore to be considered in all respects as illustrative and not restrictive, the scope of the invention being indicated by the appended claims rather than by the foregoing description, and all changes which come within the meaning and range of equivalency of the claims are therefore intended to be embraced therein. Any reference sign in a claim should not be construed as limiting the claim concerned.

Claims (6)

1. The utility model provides a cotton production of irradiation crosslinked polyethylene bubble is with design cooling device, includes cooling shell (1), its characterized in that: the front door plate (2) is arranged at the front end of the cooling shell (1), the front door plate (2) is connected with the cooling shell (1) in a rotating mode, monitoring glass (3) is arranged at the front end of the front door plate (2), a door handle (4) is arranged at the lower end of the monitoring glass (3), feeding boxes (5) are arranged on two sides of the cooling shell (1), the feeding boxes (5) are connected with the cooling shell (1) in a welding mode, a cooling fan (6) is arranged at the lower end of each feeding box (5), the cooling fans (6) are connected with the cooling shell (1) in a welding mode, a discharging port (7) is arranged at the lower end of each cooling fan (6), the discharging ports (7) and the cooling shell (1) are arranged in an integrated mode, first conveying belts (8) are arranged on two sides of the interior of the cooling shell (1), and two first conveying belts (8) are arranged, and first conveyer belt (8) and cooling housing (1) inner wall bolt fixed connection, every the top of first conveyer belt (8) all is provided with blowing spray tube (9), and blows spray tube (9) and cooling blower (6) pipe connection, every the below of first conveyer belt (8) all is provided with platform (12) of breathing in, and platform (12) and cooling blower (6) pipe connection of breathing in, every the inner wall of feed box (5) all is provided with dust strip (18), and dust strip (18) and feed box (5) inner wall bolt fixed connection.

2. The shaping and cooling device for producing the radiation crosslinked polyethylene foam as claimed in claim 1, wherein the shaping and cooling device comprises: a merging pipe (14) is arranged between the two first conveyor belts (8), a heating pipe (15) is arranged at the lower end of the merging pipe (14), and the heating pipe (15) is fixedly connected with the inner wall of the cooling shell (1) through bolts.

3. The shaping and cooling device for producing the radiation crosslinked polyethylene foam as claimed in claim 2, wherein the shaping and cooling device comprises: the lower end of the heating pipe (15) is provided with a material distribution partition plate (16), the material distribution partition plate (16) is connected with the heating pipe (15) in a welding mode, second conveyor belts (17) are arranged on two sides of the lower portion of the material distribution partition plate (16), and the second conveyor belts (17) are fixedly connected with the inner wall of the cooling shell (1) through bolts.

4. The shaping and cooling device for producing the radiation crosslinked polyethylene foam as claimed in claim 2, wherein the shaping and cooling device comprises: the inner wall of the heating pipe (15) is provided with an electric heating ring (19), the electric heating ring (19) is connected with the inner wall of the material distribution partition plate (16) in a welding mode, the inner wall of the electric heating ring (19) is provided with a material distribution inner plate (20), and the material distribution inner plate (20) is connected with the inner wall of the electric heating ring (19) in a welding mode.

5. The shaping and cooling device for producing the radiation crosslinked polyethylene foam as claimed in claim 1, wherein the shaping and cooling device comprises: the upper end of each air suction table (12) is provided with an air suction port (13), and the air suction ports (13) are connected with the air suction tables (12) in a welding mode.

6. The shaping and cooling device for producing the radiation crosslinked polyethylene foam as claimed in claim 1, wherein the shaping and cooling device comprises: the lower end of each blowing spray pipe (9) is provided with a spray nozzle (10), the lower end of each spray nozzle (10) is provided with a net-shaped spray head (11), and the net-shaped spray heads (11) are connected with the spray nozzles (10) in a welding mode.

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