CN210443341U

CN210443341U - Cable cooling device

Info

Publication number: CN210443341U
Application number: CN201921627735.1U
Authority: CN
Inventors: 李金栋
Original assignee: Yingrunjia Cable Co ltd
Current assignee: Yingrunjia Cable Co ltd
Priority date: 2019-09-27
Filing date: 2019-09-27
Publication date: 2020-05-01
Anticipated expiration: 2029-09-27

Abstract

The utility model relates to a cable manufacturing technical field especially relates to a cable cooling device. The cooling device comprises an accelerated cooling defoaming part arranged in a cooling pool and the cooling pool, and is matched with the cooling pool, so that movable plates on two sides of the accelerated cooling defoaming part are driven by a vibration motor to move up and down, the flow rate of cooling water in the cooling pool is accelerated, water flow impacts bubbles at the bottom of a cable, the cooling quality of the cable cannot be influenced due to the fact that the bubbles are attached to the surface of the cable, and the problems that the cooling efficiency of the cable is insufficient and the cooling quality of the cable is influenced due to the fact that the bubbles are attached to the surface of the cable are solved; adopt the cooperation of the board that blocks water and the baffle that blocks water that cooling tank one side set up, realized leading out the higher water of the temperature that is in high-order in the cooling tank, temperature in the cooling tank when guaranteeing to use will block water the board and take off can conveniently wash the dirt that accumulates in the cooling tank after long-time the use.

Description

Cable cooling device

Technical Field

The utility model relates to a cable manufacturing technical field especially relates to a cable cooling device.

Background

In the cable manufacturing process, a high-temperature cable which is just manufactured needs to be cooled, but due to the traditional cable cooling device, the cable is directly placed into the water tank for cooling, the cooling efficiency of the cable is not high due to the fact that the flow rate of water in the water tank is not high, the problem that the cooling of the cable is not uniform is easily caused, and due to the fact that the cable is cooled, air bubbles can be generated on the surface of the cable, and the air bubbles cannot be completely removed by the traditional cable cooling device, and therefore the air bubbles are left on the surface of the cable.

SUMMERY OF THE UTILITY MODEL

The technical problem to be solved by the utility model is to the technical insufficiency, a cable cooling device is provided, the accelerated cooling defoaming part arranged in the cooling pool is adopted to be matched with the cooling pool, the movable plates on the two sides of the accelerated cooling defoaming part are driven by the vibrating motor to move up and down, thereby accelerating the flow velocity of cooling water in the cooling pool, and the water flow impacts the bubbles at the bottom of the cable, thereby ensuring that the cooling quality of the cable is not influenced by the bubbles attached to the surface of the cable, and solving the problems that the cooling efficiency of the cable is insufficient and the cooling quality of the cable is influenced by the bubbles attached to the surface of the cable; adopt the cooperation of the board that blocks water and the baffle that blocks water that cooling tank one side set up, realized leading out the higher water of the temperature that is in high-order in the cooling tank, temperature in the cooling tank when guaranteeing to use will block water the board and take off can conveniently wash the dirt that accumulates in the cooling tank after long-time the use.

In order to solve the technical problem, the utility model discloses the technical scheme who adopts is: comprises a chassis; a cooling pool is arranged on the underframe; the cooling pool is connected with the underframe through damping springs at the periphery; the bottom of the cooling pool is connected with a vibration motor through bolts; a top cover is arranged on the upper side of the cooling pool; a cable inlet is formed in one side of the top cover; a cable outlet is formed in one side, away from the cable inlet, of the top cover; a plurality of accelerated cooling defoaming parts are symmetrically arranged on two sides of the cooling pool in the width direction; the accelerated cooling debubbling part comprises: a movable plate, a fixed column and a connecting piece; a fixed column is arranged in the middle of the accelerated cooling defoaming part; movable plates are symmetrically arranged on two sides of the fixed column; sliding grooves are formed in two sides of the movable plate; the fixed columns are welded on the bottom surface of the inner wall of the cooling pool; the middle part of the connecting piece is connected with the fixed column rotating shaft; a first sliding block is arranged at one end of the connecting piece; the first sliding block is connected in the sliding groove of the movable plate in a sliding manner; the other end of the connecting piece is provided with a second sliding block; the second sliding block is connected in the sliding groove of the other movable plate in a sliding manner; a water outlet is formed in the bottom of one side, close to the cable outlet, of the cooling pool; one side of the water outlet is provided with a water blocking plate.

Further optimize this technical scheme, the top cap is provided with the cooling water entry near cable entry one side.

Further optimizing the technical scheme, a water blocking baffle is arranged at the upper side of the water blocking plate; and two sides of the water blocking baffle are welded with the inner wall of the cooling pool.

Further optimizing the technical scheme, the cooling pool is internally and symmetrically provided with mounting columns in the length direction; and a rotating shaft in the middle of the mounting column is connected with a wire pressing roller.

According to the technical scheme, the rebound springs are arranged on the periphery of one side of the movable plate, which is close to the bottom surface of the inner wall of the cooling pool; the rebound spring is welded with the movable plate.

Further optimizing the technical scheme, the inner walls of the two sides of the water-blocking plate of the cooling pool are provided with slide rails; the water blocking plate is connected with the sliding rails of the cooling pools on the two sides in a sliding mode.

Compared with the prior art, the utility model has the advantages of it is following: 1. the structure is beneficial to ensuring that the movable plates on two sides of the accelerated cooling defoaming part are driven by the vibrating motor to move up and down, so that the flow speed of cooling water in the cooling pool is accelerated, water flow impacts bubbles at the bottom of the cable, and the cable is ensured not to influence the cooling quality of the cable due to the fact that the bubbles are attached to the surface of the cable; 2. the water blocking plate and the water blocking baffle which are arranged on one side of the cooling pool are matched, the structure is favorable for ensuring that the higher water with the high temperature in the cooling pool is led out, the water temperature in the cooling pool is ensured when the cooling pool is used, and the water blocking plate is taken down after the cooling pool is used for a long time so as to conveniently wash dirt accumulated in the cooling pool.

Drawings

Fig. 1 is a schematic view of the overall structure of a cable cooling device.

Fig. 2 is a schematic diagram of the overall structure of a cooling pool of a cable cooling device.

Fig. 3 is an enlarged partial cross-sectional structural view of a cooling pool of a cable cooling device.

Fig. 4 is a schematic view of the overall structure of an accelerated cooling and defoaming part of a cable cooling device.

Fig. 5 is a schematic view of a connector structure of a cable cooling device.

In the figure: 1. a chassis; 2. a cooling pool; 3. a damping spring; 4. a vibration motor; 5. a top cover; 6. accelerated cooling and defoaming part; 201. a water outlet; 202. a water-blocking plate; 203. a water-retaining baffle; 204. mounting a column; 205. a wire pressing roller; 501. a cable entry; 502. a cable outlet; 503. a cooling water inlet; 601. a movable plate; 602. fixing a column; 603. a connecting member; 604. a chute; 605. a first slider; 606. a second slider; 607. a rebound spring.

Detailed Description

In order to make the objects, technical solutions and advantages of the present invention more apparent, the present invention will be described in detail with reference to the accompanying drawings. It should be understood that the description is intended to be illustrative only and is not intended to limit the scope of the present invention. Moreover, in the following description, descriptions of well-known structures and techniques are omitted so as to not unnecessarily obscure the concepts of the present invention.

The specific implementation mode is as follows: shown in connection with fig. 1-5, includes a chassis 1; a cooling pool 2 is arranged on the underframe 1; the cooling pool 2 is connected with the underframe 1 through damping springs 3 at the periphery; the bottom of the cooling pool 2 is connected with a vibration motor 4 through a bolt; a top cover 5 is arranged on the upper side of the cooling pool 2; a cable inlet 501 is formed in one side of the top cover 5; a cable outlet 502 is arranged on one side of the top cover 5 far away from the cable inlet 501; a plurality of accelerated cooling and defoaming parts 6 are symmetrically arranged on two sides in the width direction in the cooling pool 2; the accelerated cooling defoaming portion 6 includes: a movable plate 601, a fixed column 602 and a connecting piece 603; a fixed column 602 is arranged in the middle of the accelerated cooling defoaming part 6; movable plates 601 are symmetrically arranged on two sides of the fixed column 602; sliding grooves 604 are formed in the two sides of the movable plate 601; the fixing columns 602 are welded on the bottom surface of the inner wall of the cooling pool 2; the middle part of the connecting piece 603 is connected with a rotating shaft of a fixed column 602; one end of the connecting piece 603 is provided with a first sliding block 605; the first sliding block 605 is slidably connected in the sliding groove 604 of the movable plate 601; the other end of the connecting piece 603 is provided with a second sliding block 606; the second sliding block 606 is slidably connected in the sliding slot 604 of the other movable plate 601; a water outlet 201 is formed in the bottom of one side, close to the cable outlet 502, of the cooling pool 2; a water blocking plate 202 is arranged on one side of the water outlet 201; a cooling water inlet 503 is formed in one side, close to the cable inlet 501, of the top cover 5; a water blocking baffle 203 is arranged at the upper side of the water blocking plate 202; two sides of the water retaining baffle 203 are welded with the inner wall of the cooling pool 2; the cooling pool 2 is internally and symmetrically provided with mounting columns 204 in the length direction; a wire pressing roller 205 is connected with a rotating shaft in the middle of the mounting column 204; a rebound spring 607 is arranged on the periphery of one side of the movable plate 601 close to the bottom surface of the inner wall of the cooling pool 2; the rebound spring 607 is welded with the movable plate 601; sliding rails are arranged on the inner walls of the two sides of the water blocking plate 202 of the cooling pool 2; the water blocking plate 202 is connected with the slide rails of the cooling pools 2 at two sides in a sliding manner.

When in use, as shown in fig. 1-5, a cable enters the cooling pool 2 through the cable inlet, and is discharged from the cable outlet through the two wire pressing rollers 205, cooling water enters the cooling pool 2 through the cooling water inlet 503, when the cooling pool 2 is in use, the vibration motor 4 is arranged below the cooling pool 2, so that the cooling pool 2 vibrates, and at this time, the movable plate 601 at the two sides of the cooling defoaming portion 6 is initially at a balanced position, the movable plate 601 at the two sides of the cooling defoaming portion 6 starts to move up and down, the first sliding block 605 at one side of the connecting member 603 slides along the sliding groove 604 of the movable plate 601 at one side, so that the movable plate 601 is at an upper position, at this time, the movable plate 601 at the other side is pressed to a lower position by the second sliding block 606 at the other side of the connecting member 603, the rebound spring 607 below the movable plate 601 at the other side compresses the stored force, the stored force of the rebound spring 607 below the, also make the first movable plate 601 and the second movable plate 601 of both sides realize the activity from top to bottom, when first movable plate 601 and the second movable plate 601 move from top to bottom, make the velocity of flow of the cooling water in cooling tank 2 improved, the cooling water is by the even cable towards the middle part of washing away, the cooling function to the cable has been realized, also guaranteed the cleaing away to the outer adnexed bubble of cable, cable cooling quality has been guaranteed, because cooling tank 2 delivery port 201 is provided with water blocking plate 202 and water blocking baffle 203, make the high temperature cooling water that leans on the upper position in cooling tank 2 can discharge through delivery port 201, and the low temperature cooling water that leans on the lower position can remain in cooling tank 2, treat after cooling tank 2 uses for a long time, can take off water blocking plate 202, realize the function of the spot of convenient clean cooling tank 2 bottom.

The utility model discloses a control mode comes automatic control through the controller, and the control circuit of controller can realize through the simple programming of technical staff in this field, belongs to the common general knowledge in this field, and the utility model discloses mainly be used for protecting the machinery setting, so the utility model discloses no longer explain control mode and circuit connection in detail.

It is to be understood that the above-described embodiments of the present invention are merely illustrative of or explaining the principles of the invention and are not to be construed as limiting the invention. Therefore, any modification, equivalent replacement, improvement and the like made without departing from the spirit and scope of the present invention should be included in the protection scope of the present invention. Further, it is intended that the appended claims cover all such variations and modifications as fall within the scope and boundaries of the appended claims or the equivalents of such scope and boundaries.

Claims

1. A cable cooling device, characterized by: comprises a chassis (1); a cooling pool (2) is arranged on the underframe (1); the cooling pool (2) is connected with the underframe (1) through damping springs (3) at the periphery; the bottom of the cooling pool (2) is connected with a vibration motor (4) through a bolt; a top cover (5) is arranged on the upper side of the cooling pool (2); a cable inlet (501) is formed in one side of the top cover (5); a cable outlet (502) is formed in one side, away from the cable inlet (501), of the top cover (5); a plurality of accelerated cooling and defoaming parts (6) are symmetrically arranged on two sides of the cooling pool (2) in the width direction; the accelerated cooling debubbling section (6) includes: a movable plate (601), a fixed column (602) and a connecting piece (603); a fixed column (602) is arranged in the middle of the accelerated cooling defoaming part (6); movable plates (601) are symmetrically arranged on two sides of the fixed column (602); sliding grooves (604) are formed in two sides of the movable plate (601); the fixing columns (602) are welded on the bottom surface of the inner wall of the cooling pool (2); the middle part of the connecting piece (603) is connected with a rotating shaft of the fixed column (602); one end of the connecting piece (603) is provided with a first sliding block (605); the first sliding block (605) is connected in a sliding way in the sliding groove (604) of the movable plate (601); the other end of the connecting piece (603) is provided with a second sliding block (606); the second sliding block (606) is connected in a sliding way in the sliding groove (604) of the other movable plate (601); a water outlet (201) is formed in the bottom of one side, close to the cable outlet (502), of the cooling pool (2); one side of the water outlet (201) is provided with a water-blocking plate (202).

2. A cable cooling device as claimed in claim 1, characterized in that: and a cooling water inlet (503) is formed in one side, close to the cable inlet (501), of the top cover (5).

3. A cable cooling device as claimed in claim 1, characterized in that: a water blocking baffle (203) is arranged at the upper side of the water blocking plate (202); and two sides of the water blocking baffle (203) are welded with the inner wall of the cooling pool (2).

4. A cable cooling device as claimed in claim 1, characterized in that: the cooling pool (2) is internally and symmetrically provided with mounting columns (204) in the length direction; and a line pressing roller (205) is connected with a rotating shaft in the middle of the mounting column (204).

5. A cable cooling device as claimed in claim 1, characterized in that: the periphery of one side, close to the bottom surface of the inner wall of the cooling pool (2), of the movable plate (601) is provided with a rebound spring (607); the rebound spring (607) is welded with the movable plate (601).

6. A cable cooling device as claimed in claim 1, characterized in that: sliding rails are arranged on the inner walls of the two sides of the water blocking plate (202) of the cooling pool (2); the water blocking plate (202) is connected with the sliding rails of the cooling pools (2) on the two sides in a sliding mode.