CN214521411U - Cable cooling system - Google Patents

Abstract

The application relates to a cable cooling system, it includes the cooling bath, its characterized in that: a partition plate is fixedly arranged in the cooling tank along the vertical direction, a spray pipe is arranged on the cooling tank, and a water outlet of the spray pipe is positioned on one side of the partition plate close to the feeding end of the cooling tank; the cooling tank is provided with a water inlet pipe, and the water outlet of the water inlet pipe is positioned on one side of the partition plate, which is far away from the feed end of the cooling tank. When the cable needs to be sprayed and cooled, the spraying pipe sprays water to spray and cool the cable, at the moment, the water inlet pipe is closed, no water is accumulated in the cooling tank, and the spraying operation is convenient to normally carry out; when needs soak the cooling to the cable, the shower was closed this moment, and the inlet tube is opened, has held the coolant liquid in making the cooling bath, and the division board separates the shelves with the coolant liquid on required position, and the cooling bath of being convenient for carries out the cooling operation of soaking to the cable, and this application has the effect that makes the cooling bath can satisfy the different cooling demands of multiple cable in process of production.

Description

Cable cooling system

Technical Field

The present application relates to the field of cables, and more particularly, to a cable cooling system.

Background

Cables (e.g., electrical cables, optical cables, etc.) are widely used in daily life, and are used in household life and industrial production. Generally, a cable includes a cable core, a shielding layer, a protective layer, and the like. The current cable cooling device is mainly used for cooling the cable in the manufacturing process of the cable.

The traditional Chinese patent with publication number CN104021887A discloses a cable cooling device, which comprises an upper spraying device and a lower spraying device which are oppositely arranged, wherein an upper groove is formed in the lower surface of the upper spraying device, a lower groove is formed in the upper surface of the lower spraying device, the upper groove and the lower groove form a complete channel, a closed accommodating cavity and a water inlet pipe communicated with the closed accommodating cavity are respectively arranged in the bodies of the upper spraying device and the lower spraying device, and drain holes are uniformly distributed in the groove walls of the upper groove and the lower groove and communicated with the closed accommodating cavity.

In view of the above-mentioned related technologies, the inventor found that, in the cable production process, some cables need spray cooling, some cables need soak cooling, and it is difficult for one cooling device to achieve different cooling requirements of multiple cables.

SUMMERY OF THE UTILITY MODEL

In order that cooling device can satisfy the different cooling demands of multiple cable in process of production, this application provides a cable cooling system.

The application provides a cable cooling system adopts following technical scheme:

a cable cooling system, includes cooling bath, its characterized in that: a partition plate is fixedly arranged in the cooling tank along the vertical direction, a spray pipe is arranged on the cooling tank, and a water outlet of the spray pipe is positioned on one side of the partition plate close to the feeding end of the cooling tank; the cooling tank is provided with a water inlet pipe, and the water outlet of the water inlet pipe is positioned on one side of the partition plate, which is far away from the feed end of the cooling tank.

By adopting the technical scheme, the cooling groove cools the cable, when the cable needs to be sprayed and cooled, the spraying pipe sprays water to spray and cool the cable, at the moment, the water inlet pipe is closed, no water is accumulated in the cooling groove, and the normal spraying operation is facilitated; when the cable is soaked and cooled as required, the spray pipe is closed at the moment, the water inlet pipe is opened, the cooling liquid is contained in the cooling tank, the partition plate separates the cooling liquid at a required position, the cooling tank is convenient for soaking and cooling the cable, and the cooling tank can meet different cooling requirements of various cables in the production process.

Optionally, the end of the partition plate, which is far away from the feed end of the cooling tank, is rotatably connected with a plurality of lower guide wheels in the vertical direction, the lower guide wheels are arranged in the length direction of the cooling tank and are arranged in parallel with a plurality of rows, and the lower guide wheels are provided with lower guide grooves in the circumferential direction of the lower guide wheels.

Through adopting above-mentioned technical scheme, when the cooling bath carries out cooling operation to the cable, lower leading wheel plays the guide effect to the cable, and the multirow leading wheel is convenient for the cooling bath and carries out cooling operation to many cables simultaneously, makes the cooling process more high-efficient orderly, and when the cable removed, in the lower leading groove was arranged in to the cable, the lower leading groove made the removal orbit of cable more stable difficult skew.

Optionally, a support plate arranged in the vertical direction to slide is arranged on the cooling tank along the horizontal direction, a plurality of upper guide wheels opposite to the lower guide wheels are rotatably connected to the support plate along the vertical direction, and an upper guide groove is formed in the upper guide wheels along the circumferential direction of the upper guide wheels.

Through adopting above-mentioned technical scheme, when the cooling bath during operation, go up the leading wheel and cooperate with lower leading wheel, make the cable arrange in and go up the leading groove and remove with lower leading groove, and then make the removal process of cable more stable, go up the leading wheel simultaneously and move down and make the cable can soak in the coolant liquid better.

Optionally, the lower terminal surface of backup pad both sides has set firmly the lift screw rod along vertical direction, rotates along the horizontal direction on the cooling bath to be connected with lift screw rod threaded connection's lift helical gear, rotates along vertical direction on the cooling bath to be connected with the rotation helical gear that goes up and down helical gear meshing and be connected.

Through adopting above-mentioned technical scheme, rotation helical gear rotates and drives the rotation of lift helical gear, and the lift helical gear makes the lift screw rod move in vertical direction, and the lift screw rod drives the backup pad lift, and then realizes the height control function of upper guide wheel.

Optionally, a synchronization rod is arranged on the cooling tank along the horizontal direction, and two ends of the synchronization rod are respectively and coaxially and fixedly connected with the opposite rotating bevel gears.

Through adopting above-mentioned technical scheme, when rotating the rotation helical gear, the synchronizing bar realizes the synchronous rotation of two rotation helical gears, and then makes the backup pad in lift in-process both ends synchronous motion, keeps going up and down on the level attitude better.

Optionally, two water outlet pipes are fixedly arranged at the bottom end of the cooling tank, the joints of the water outlet pipes and the cooling tank are respectively located at two sides of the partition plate, control valves are arranged on the water outlet pipes, a circulating water tank is fixedly arranged at the lower end of each water outlet pipe, and the cooling pipes are communicated with the circulating water tank and the cooling tank.

Through adopting above-mentioned technical scheme, when the coolant liquid temperature after the use became high, opened control flap and made the higher coolant liquid of temperature discharge to circulation tank in, circulation tank collected the coolant liquid and deposited and be convenient for carry out subsequent relevant application, reduced the wasting of resources to a certain extent.

Optionally, a circulating water pump is fixedly arranged on the circulating water tank, a circulating water pipe is arranged on the circulating water pump, and the circulating water tank is communicated with the spray pipe and the water inlet pipe through the circulating water pipe.

Through adopting above-mentioned technical scheme, after the coolant liquid in the circulating water tank resumes the lower temperature, circulating water pump makes coolant liquid follow shower and inlet tube discharge once more through circulating water pipe and carries out cooling operation to the cable, realizes the circulative cooling of coolant liquid.

Optionally, the side walls of the discharge ends of the partition plate and the cooling tank are both provided with channel grooves along the vertical direction, the height of each channel groove is higher than that of the lower guide wheel, and the side walls of the discharge ends of the partition plate and the cooling tank are both internally connected with flexible water absorbing layers in a sliding mode along the vertical direction.

Through adopting above-mentioned technical scheme, after the cooling operation of cable was accomplished, the cable shifted out the cooling bath through the channel groove, and the flexible layer that absorbs water dries the coolant liquid on cable surface this moment, need not the user and dries the cable, and the follow-up operation of being convenient for goes on smoothly.

In summary, the present application includes at least one of the following beneficial technical effects:

1. the cooling groove cools the cable, when the cable needs to be sprayed and cooled, the spraying pipe sprays water to spray and cool the cable, the water inlet pipe is closed at the moment, no water is accumulated in the cooling groove, and the spraying operation is convenient to normally carry out; when the cable is soaked and cooled as required, the spray pipe is closed at the moment, the water inlet pipe is opened, the cooling liquid is contained in the cooling tank, the partition plate separates the cooling liquid at a required position, the cooling tank is convenient for soaking and cooling the cable, and the cooling tank can meet different cooling requirements of various cables in the production process.

2. When the cooling tank carries out cooling operation to the cable, lower leading wheel plays the guide effect to the cable, and the multirow leading wheel is convenient for the cooling tank and is carried out cooling operation to many cables simultaneously, makes the cooling process more high-efficient orderly, and when the cable removed, the cable was arranged in lower leading groove, and lower leading groove made the removal orbit of cable more stable difficult skew.

3. When the cooling tank during operation, go up the leading wheel and cooperate with lower leading wheel, make the cable arrange in the upper leading groove and remove with lower leading groove, and then make the removal process of cable more stable, go up the leading wheel and move down simultaneously and make the cable can soak in the coolant liquid better.

Drawings

Fig. 1 is a schematic structural diagram of an embodiment of the present application.

Fig. 2 is a sectional view of a lower guide groove and a lower guide wheel in the embodiment of the present application.

Fig. 3 is a partially enlarged view of a in fig. 1.

Description of reference numerals: 1. a cooling tank; 2. a partition plate; 3. a shower pipe; 4. a water inlet pipe; 5. a lower guide wheel; 6. a lower guide groove; 7. a support plate; 8. an upper guide wheel; 9. an upper guide groove; 10. a lifting screw; 11. lifting the bevel gear; 12. rotating the bevel gear; 13. a synchronization lever; 14. a water outlet pipe; 15. a control valve; 16. a circulating water tank; 17. a water circulating pump; 18. a circulating water pipe; 19. a channel groove; 20. a flexible water-absorbing layer; 21. a spray tank; 22. a soaking tank; 23. a sliding groove; 24. wiping the seams dry; 25. a cooling device; 26. a guide post; 27. a sliding post; 28. the handle is rotated.

Detailed Description

The present application is described in further detail below with reference to the accompanying drawings.

The embodiment of the application discloses cable cooling system, refer to fig. 1, including cooling bath 1, the position that is close to 1 feed end of cooling bath has set firmly division board 2 along vertical direction in the cooling bath 1, and division board 2 separates cooling bath 1 for spray tank 21 and soaking groove 22 two parts, and the length that soaks groove 22 is greater than the length that sprays tank 21. When the cooling tank 1 performs the cooling operation on the cable, the user performs the cooling operation according to the specific requirements of the cable: when the cable needs to be cooled by spraying, a user cools the cable in the spraying groove 21; when the cable needs to be soaked for cooling, the user cools the cable within the soaking bath 22.

Referring to fig. 1, a spray pipe 3 is provided on a cooling bath 1, and a water outlet of the spray pipe 3 is located at an upper side of a spray bath 21. When the user need spray the cooling to the cable, the cable removes along the length direction of cooling bath 1, and the user starts shower 3 this moment and makes shower 3 spray water and spray the cooling to the cable, realizes spraying the cooling function.

Referring to fig. 1, the shower pipe 3 has a bamboo tube shape. When the shower 3 sprays the operation, the user adjusts the spray angle of shower 3 according to the cooling demand of cable, and then makes the spray cooling function of shower 3 more perfect.

Referring to fig. 1 and 2, a water inlet pipe 4 is arranged on the soaking tank 22, and a water outlet of the water inlet pipe 4 is positioned above the soaking tank 22. When a user needs to spray and cool the cable, the user closes the water inlet pipe 4, no cooling liquid exists in the soaking groove 22, and the cable after being sprayed and cooled is directly moved out of the cooling groove 1 through the soaking groove 22, so that the spraying operation can be conveniently and normally carried out; when the user need soak the cooling to the cable, the user closed shower 3 this moment, opens inlet tube 4, has held the coolant liquid in messenger soaks groove 22, when the cable was arranged in the cooling bath 1 and is removed, and the coolant liquid soaks the cooling operation to the cable.

Referring to fig. 1 and 2, two channel grooves 19 perpendicular to each other are formed in the side walls of the partition plate 2 and the discharge end of the cooling tank 1 along the vertical direction. When the cooling groove 1 cools the cables, the cables penetrate through the channel grooves 19, the channel grooves 19 limit the movement of the cables, so that the cables can be conveniently and orderly arranged in the cooling groove 1 to move, and the cooling groove 1 can cool the cables.

Referring to fig. 1 and 2, a sliding groove 23 is formed in the side walls of the discharge ends of the partition plate 2 and the cooling tank 1 in the vertical direction, and a flexible water absorbing layer 20 is connected in the sliding groove 23 in the vertical direction in a sliding manner. When the cooling operation of the cable is completed, the cable is moved out of the spraying groove 21 and the soaking groove 22 through the channel groove 19, and the flexible water absorption layer 20 dries the cooling liquid on the surface of the cable at the moment, so that a user does not need to dry the cable.

Referring to fig. 1 and 2, a wiping seam 24 is formed in the flexible water absorbing layer 20 along the vertical direction, and a cable is slidably connected with the wiping seam 24. When the flexible water absorption layer 20 is used for wiping the cable, the cable penetrates through the wiping gaps 24, so that the moisture on the surface of the cable is thoroughly wiped, and meanwhile, the wiping gaps 24 further play a role in guiding the movement of the cable, so that the displacement track of the cable is more stable.

Referring to fig. 1 and 2, two water outlet pipes 14 are fixedly arranged at the bottom end of the cooling tank 1, the water outlet pipes 14 are respectively and fixedly connected with the bottom ends of the spraying tank 21 and the soaking tank 22, a control valve 15 is arranged on the cooling pipe, a circulating water tank 16 is fixedly arranged at the lower end of each water outlet pipe 14, and the cooling pipe is communicated with the circulating water tank 16 and the cooling tank 1. When the temperature of the used cooling liquid becomes high, a user opens the control valve 15 to enable the cooling liquid with the high temperature to flow downwards and be discharged into the circulating water tank 16, and the circulating water tank 16 collects and stores the cooling liquid, so that the resource waste is reduced to a certain extent.

Referring to fig. 1 and 2, a circulating water pump 17 is fixedly arranged on the circulating water tank 16, a circulating water pipe 18 is arranged on the circulating water pump 17, and the circulating water tank 16 is communicated with the spray pipe 3 and the water inlet pipe 4 through the circulating water pipe 18. When the cooling liquid in the circulating water tank 16 returns to a lower temperature, the user starts the circulating water pump 17 to discharge the cooling liquid from the spray pipe 3 and the water inlet pipe 4 again through the circulating water pipe 18 to cool the cable, so that the circulating cooling of the cooling liquid is realized.

Referring to fig. 1 and 2, a cooling device 25 is fixedly installed on the circulation tank 16. After the circulation water tank 16 collects the cooling liquid with a higher temperature, the cooling device 25 performs a rapid cooling operation on the cooling liquid, so that the cooling liquid can be rapidly cooled to a desired temperature, thereby facilitating the circulation process.

Referring to fig. 1 and 2, the end of the partition plate 2 far away from the feed end of the cooling tank 1 is rotatably connected with six lower guide wheels 5 along the vertical direction, the height of the lower guide wheels 5 is lower than that of the channel groove 19, the lower guide wheels 5 are arranged along the length direction of the cooling tank 1 and are arranged in two rows side by side, and the connecting line of the lower guide wheels 5 and the channel eraser is arranged along the length direction of the cooling tank 1. When the cooling tank 1 cools the cable, the cable and the lower guide wheel 5 are connected in an abutting mode, the lower guide wheel 5 rotates to guide the cable, the two rows of lower guide wheels 5 facilitate the cooling tank 1 to cool two cables simultaneously, and the cooling process is efficient and orderly.

Referring to fig. 1 and 2, a lower guide groove 6 is formed on an outer wall of the lower guide wheel 5 along a circumferential direction of the lower guide wheel 5. When the cable moves along the length direction of the cooling groove 1, the cable is arranged in the lower guide groove 6 and is in sliding connection with the lower guide groove 6, and the lower guide groove 6 enables the moving track of the cable to be more stable and not easy to deviate.

Referring to fig. 1 and 2, a support plate 7 which is arranged to move in the vertical direction is movably connected to the cooling tank 1 in the horizontal direction, six upper guide wheels 8 which are opposite to the lower guide wheels 5 are rotatably connected to the lower end faces of the support plate 7 in the vertical direction, the upper guide wheels 8 are arranged right above the lower guide wheels 5, and upper guide grooves 9 are formed in the upper guide wheels 8 along the circumferential direction of the upper guide wheels 8. When the cooling tank 1 is in operation, the supporting plate 7 is lifted to drive the upper guide wheel 8 to lift, the upper guide wheel 8 is matched with the lower guide wheel 5 at the moment, the cable is placed between the upper guide groove 9 and the lower guide groove 6 to move, the moving process of the cable is further stable, and meanwhile the upper guide wheel 8 moves downwards to enable the cable to be better soaked in the cooling liquid.

Referring to fig. 1 and 3, two lifting screws 10 are fixedly arranged on the lower end surfaces of two sides of the supporting plate 7 along the vertical direction, a lifting helical gear 11 in threaded connection with the lifting screws 10 is rotatably connected to the cooling tank 1 along the horizontal direction, and a rotating helical gear 12 in meshed connection with the lifting helical gear 11 is rotatably connected to the cooling tank 1 along the vertical direction. When the height of the supporting plate 7 needs to be changed, a user enables the rotating bevel gear 12 to rotate to drive the lifting bevel gear 11 to rotate, the lifting bevel gear 11 enables the lifting screw 10 to move in the vertical direction, the lifting screw 10 further drives the supporting plate 7 to lift, and the supporting plate 7 drives the upper guide wheel 8 to move to achieve the height adjusting function of the upper guide wheel 8.

Referring to fig. 1 and 2, four guide columns 26 in a cylindrical shape are fixedly arranged on the cooling tank 1 along the vertical direction, a sliding column 27 in a cylindrical shape is fixedly arranged on the lower end surface of the supporting plate 7 along the vertical direction, and the sliding column 27 is connected with the guide columns 26 in a sliding manner along the vertical direction. When the support plate 7 moves in the vertical direction, the guide post 26 moves in the sliding post 27, and the guide post 26 and the sliding post 27 are matched to make the displacement process of the support plate 7 more stable and not easy to shift.

Referring to fig. 2 and 3, a synchronization rod 13 is disposed on the cooling tank 1 along the horizontal direction, and both ends of the synchronization rod 13 are coaxially and fixedly connected to the two rotating helical gears 12, respectively. When the rotating bevel gears 12 are rotated, the synchronizing rod 13 rotates to realize the synchronous rotation of the two rotating bevel gears 12, so that the two ends of the supporting plate 7 move synchronously in the lifting process, and the lifting is better kept in a horizontal state.

Referring to fig. 1 and 3, the cooling tank 1 is provided with a rotating handle 28, and the rotating handle 28 is coaxially and fixedly connected with one of the rotating bevel gears 12. When the user needs to move the support plate 7, the rotation of the rotary bevel gear 12 is achieved by rotating the rotary handle 28, so that the lifting process of the support plate 7 is smoother.

The implementation principle of a cable cooling system in the embodiment of the application is as follows: before the cooling tank 1 works, a user adjusts the height of the upper guide wheel 8 according to the diameter of the cable, the rotating bevel gear 12 rotates through the rotating handle 28, the rotating bevel gear 12 rotates to drive the lifting bevel gear 11 to rotate, the lifting bevel gear 11 enables the lifting screw 10 to move in the vertical direction, the lifting screw 10 enables the support plate 7 to drive the upper guide wheel 8 to move, and when the cable moves along the length direction of the cooling tank 1, the upper guide wheel 8 and the lower guide wheel 5 guide the cable. When the cable needs to be sprayed and cooled, the spraying pipe 3 sprays water to spray and cool the cable, at the moment, the water inlet pipe 4 is closed, and no cooling liquid exists in the soaking groove 22; when the cable needs to be soaked and cooled, the spraying pipe 3 is closed, the water inlet pipe 4 is opened, and cooling liquid is contained in the soaking groove 22. When the cooling operation of the cable is completed, the cable is moved out of the spraying groove 21 and the soaking groove 22 through the channel groove 19, and the flexible water absorption layer 20 dries the cooling liquid on the surface of the cable, so that the cooling operation of the cable is completed.

The above embodiments are preferred embodiments of the present application, and the protection scope of the present application is not limited by the above embodiments, so: all equivalent changes made according to the structure, shape and principle of the present application shall be covered by the protection scope of the present application.

Claims (8)

1. A cable cooling system comprising a cooling tank (1), characterized in that: a partition plate (2) is fixedly arranged in the cooling tank (1) along the vertical direction, a spray pipe (3) is arranged on the cooling tank (1), and a water outlet of the spray pipe (3) is positioned on one side, close to the feeding end of the cooling tank (1), of the partition plate (2); a water inlet pipe (4) is arranged on the cooling tank (1), and a water outlet of the water inlet pipe (4) is positioned on one side of the partition plate (2) far away from the feed end of the cooling tank (1).

2. A cable cooling system according to claim 1, wherein: the end part, far away from the feeding end of the cooling tank (1), of the partition plate (2) is rotatably connected with a plurality of lower guide wheels (5) in the vertical direction, the lower guide wheels (5) are arranged in the length direction of the cooling tank (1) and are arranged in parallel, and the lower guide grooves (6) are formed in the lower guide wheels (5) in the circumferential direction of the lower guide wheels (5).

3. A cable cooling system according to claim 2, wherein: the cooling groove (1) is provided with a supporting plate (7) which slides in the vertical direction along the horizontal direction, the supporting plate (7) is rotatably connected with a plurality of upper guide wheels (8) opposite to the lower guide wheels (5) along the vertical direction, and the upper guide grooves (9) are formed in the upper guide wheels (8) along the circumferential direction of the upper guide wheels (8).

4. A cable cooling system according to claim 3, wherein: the lower terminal surface of backup pad (7) both sides has set firmly lift screw (10) along vertical direction, rotates along the horizontal direction on cooling tank (1) to be connected with lift screw (10) threaded connection's lift helical gear (11), rotates along vertical direction on cooling tank (1) to be connected with rotation helical gear (12) that are connected with lift helical gear (11) meshing.

5. A cable cooling system according to claim 4, wherein: and a synchronous rod (13) is arranged on the cooling tank (1) along the horizontal direction, and two ends of the synchronous rod (13) are respectively and coaxially and fixedly connected with the opposite rotating bevel gears (12).

6. A cable cooling system according to claim 1, wherein: the bottom of cooling tank (1) sets firmly two outlet pipes (14), and the junction of outlet pipe (14) and cooling tank (1) is located the both sides of division board (2) respectively, is equipped with control flap (15) on outlet pipe (14), and the lower extreme of outlet pipe (14) sets firmly circulation tank (16), and the cooling tube intercommunication circulation tank (16) and cooling tank (1).

7. A cable cooling system according to claim 6, wherein: and a circulating water pump (17) is fixedly arranged on the circulating water tank (16), a circulating water pipe (18) is arranged on the circulating water pump (17), and the circulating water tank (16) is communicated with the spray pipe (3) and the water inlet pipe (4) through the circulating water pipe (18).

8. A cable cooling system according to claim 1, wherein: and channel grooves (19) are formed in the side walls of the discharge ends of the partition plates (2) and the cooling tank (1) in the vertical direction, the height of each channel groove (19) is higher than that of the lower guide wheel (5), and flexible water absorbing layers (20) are connected in the side walls of the discharge ends of the partition plates (2) and the cooling tank (1) in a sliding mode in the vertical direction.

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