A cooling tank for cable sheath production

Abstract

The utility model relates to cable sheath production and processing technical field discloses a cooling tank for cable sheath production, including the groove body, the bottom end welding of groove body is provided with support frame, one end of support frame is installed the fan, both sides of groove body top one end all are installed the mounting panel, one end of two mounting panels is integrally provided with the hollow ring, the inside of hollow ring evenly is provided with a plurality of inclined spray heads. In the utility model, the cable sheath driven in the assembly line operation can pass through the middle part of the hollow ring when moving out of the groove body after water cooling, the air outside is extracted by the fan at the bottom end of the support frame, and then is sent into the hollow ring through the air pipe, the air is discharged through a plurality of inclined spray heads, so that the water droplets remaining on the surface of the cable sheath can be blown off, and a plurality of inclined spray heads are inclined away from the groove body, so that water droplets can be prevented from dropping in the hollow ring, and the contact corrosion of the hollow ring by water is reduced.

Description

Technical Field

[0001] This utility model relates to the field of cable sheath production and processing technology, and in particular to a cooling tank for cable sheath production. Background Technology

[0002] Cable sheath production is typically a streamlined process. Plastic or rubber materials are extruded into tubular shapes using an extruder, followed by cooling and shaping steps to ultimately form the cable sheath. During production, a cold water tank cools the extruded cable sheath, allowing it to solidify. The cold water in the tank exchanges heat with the cable sheath surface, carrying away heat and rapidly lowering the surface temperature to achieve solidification.

[0003] Traditional cold water tanks used in cable sheath production lack the structure to treat residual moisture on the cable sheath surface after water cooling. This residual moisture forms a water film on the cable sheath surface, accelerating oxidation and corrosion. Oxidation and corrosion lead to a decline in cable sheath performance and a shortened service life.

[0004] Therefore, those skilled in the art have provided a cooling tank for cable sheath production to solve the problems mentioned in the background art. Utility Model Content

[0005] The purpose of this invention is to address the shortcomings of existing technologies by proposing a cooling tank for cable sheath production. During assembly line operations, when the cable sheaths are removed from the tank after water cooling, they pass through the center of a hollow ring. A fan at the bottom of the support frame draws in outside air, which is then sent into the hollow ring through a duct. The air is discharged through multiple angled nozzles, which blow off any water droplets remaining on the surface of the cable sheaths. Furthermore, the multiple angled nozzles are tilted away from the tank to prevent water droplets from falling into the hollow ring, reducing contact corrosion. The hollow ring is designed as a detachable module, facilitating its replacement.

[0006] To achieve the above objectives, the present invention provides the following technical solution:

[0007] A cooling tank for cable sheath production includes a tank body, a support frame welded to the bottom end of the tank body, a fan installed at one end of the support frame, mounting plates installed on both sides of the top end of the tank body, a hollow ring integrally formed at one end of each of the two mounting plates, a plurality of inclined nozzles evenly arranged on the inner side of the hollow ring, the plurality of inclined nozzles being inclined away from the tank body, and an air duct provided at the air outlet end of the fan, the tail end of the air duct being threadedly connected to the bottom end of the hollow ring;

[0008] Through the above technical solution, when the cable sheath of the transmission cable is removed from the tank after water cooling during the assembly line operation, it passes through the middle of the hollow ring. The fan at the bottom of the support frame draws in outside air and then sends it into the hollow ring through the air duct. The air is discharged through multiple angled nozzles, which can blow off the water droplets remaining on the surface of the cable sheath. Moreover, the multiple angled nozzles are all tilted away from the tank, which can prevent water droplets from dripping into the hollow ring and reduce the contact corrosion of water on the hollow ring. By designing the hollow ring as a detachable module, it is convenient to replace the hollow ring.

[0009] Furthermore, a drive motor is installed at both ends of one side of the tank, and a stirring roller is fixedly installed at the output end of each of the two drive motors. One end of each of the two stirring rollers is rotatably connected to the inner wall of the tank, and multiple sets of stirring rods are evenly arranged on the outer side of the two stirring rollers.

[0010] The above technical solution involves installing stirring rollers at both ends inside the tank. The stirring rollers are rotated by the operation of the drive motor, which can stir the water inside the tank, thus avoiding local overheating of the water and affecting the water cooling effect, thereby improving the water cooling effect of the cable sheath.

[0011] Furthermore, a plurality of support plates are welded to the inner bottom end of the tank, and a second roller is rotatably mounted at the top center of each support plate;

[0012] The above technical solution involves welding multiple support plates to the inner bottom of the tank, with a second roller rotatably mounted at the top center of each support plate. This facilitates support for the cable sheaths passing through the tank during the assembly line operation of cable sheath processing, preventing the cable sheaths from sinking to the bottom and causing wear.

[0013] Furthermore, a fixing groove is provided on both sides of the top of the groove, and a first roller is rotatably provided in the middle of the two fixing grooves;

[0014] With the above technical solution, a fixing groove is provided on both sides of the top of the trough, and a first roller is rotatably installed in the middle of the two fixing grooves, which can reduce the wear of the cable sheath when passing through the trough.

[0015] Furthermore, drainage outlets are provided on both sides of the inner bottom end of the tank, and drainage pipes are connected to the bottom ends of the two drainage outlets;

[0016] With the above technical solution, drainage outlets are provided on both sides of the inner bottom of the tank, and drainage pipes are connected to the bottom of the two drainage outlets to facilitate the drainage of water from inside the tank out of the tank.

[0017] Furthermore, a control valve is fixedly installed at the output end of the drain pipe;

[0018] The above technical solution allows for the fixed installation of a control valve at the output end of the drain pipe, thus facilitating the control of the drainage flow rate.

[0019] Furthermore, a pair of fixing bolts are installed at the connection points between the two mounting plates and the groove;

[0020] The above technical solution facilitates the replacement of the hollow ring by installing a pair of fixing bolts at the connection points between the two mounting plates and the groove.

[0021] This utility model has the following beneficial effects:

[0022] 1. The present invention proposes a cooling tank for cable sheath production. When the cable sheaths are removed from the tank after water cooling during the assembly line operation, they pass through the middle of a hollow ring. The fan at the bottom of the support frame draws in outside air and sends it into the hollow ring through the air duct. The air is discharged through multiple angled nozzles, which blows off the water droplets remaining on the surface of the cable sheaths. The multiple angled nozzles are all tilted away from the tank to prevent water droplets from dripping into the hollow ring and reduce the contact corrosion of the hollow ring by water. By designing the hollow ring as a detachable module, it is convenient to replace the hollow ring.

[0023] 2. The present invention proposes a cooling tank for cable sheath production. Stirring rollers are installed at both ends inside the tank. The stirring rollers are rotated by the operation of a drive motor, which can stir the water inside the tank and avoid local overheating of the water, thereby affecting the water cooling effect and improving the water cooling effect of the cable sheath. Multiple support plates are welded to the bottom of the tank, and a second roller is rotatably installed at the top center of each support plate. This facilitates the support of the cable sheaths passing through the tank during the assembly line operation of cable sheath processing, and prevents the cable sheaths from sinking to the bottom and causing wear. Attached Figure Description

[0024] Figure 1 This is an isometric view of a cooling tank for cable sheath production proposed in this utility model;

[0025] Figure 2 This is a cross-sectional view of a cooling tank for cable sheath production according to the present invention.

[0026] Figure 3 This is an isometric view of the hollow ring of a cooling tank for cable sheath production according to the present invention.

[0027] Figure 4 This is an isometric view of a support plate for a cooling tank used in cable sheath production according to the present invention.

[0028] Figure 5This is an isometric view of the stirring roller of a cooling tank for cable sheath production proposed in this utility model.

[0029] Legend:

[0030] 1. Support frame; 2. Tank body; 3. Fan; 4. Air duct; 5. Hollow ring; 6. Angled nozzle; 7. Mounting plate; 8. Fixing bolts; 9. Fixing groove; 10. First roller; 11. Drive motor; 12. Stirring roller; 13. Stirring rod; 14. Support plate; 15. Second roller; 16. Drain outlet; 17. Drain pipe; 18. Control valve. Detailed Implementation

[0031] The technical solutions of the present utility model will be clearly and completely described below with reference to the accompanying drawings. Obviously, the described embodiments are only some embodiments of the present utility model, and not all embodiments. Based on the embodiments of the present utility model, all other embodiments obtained by those of ordinary skill in the art without creative effort are within the protection scope of the present utility model.

[0032] Reference Figure 1-5 This utility model provides an embodiment of a cooling tank for cable sheath production, comprising a tank body 2, a support frame 1 welded to the bottom of the tank body 2, a fan 3 mounted on one end of the support frame 1, mounting plates 7 mounted on both sides of the top end of the tank body 2, and a hollow ring 5 integrally formed on one end of each mounting plate 7. Multiple angled nozzles 6 are evenly arranged inside the hollow ring 5, all angled away from the tank body 2. An air duct 4 is provided at the air outlet of the fan 3, and the tail end of the air duct 4 is threadedly connected to the bottom end of the hollow ring 5. Due to the assembly line operation... When the cable sheath of the transmission cable is removed from the tank 2 after water cooling, it passes through the middle of the hollow ring 5. The fan 3 at the bottom of the support frame 1 draws in outside air and sends it into the hollow ring 5 through the air duct 4. The air is discharged through multiple angled nozzles 6, which blows off the water droplets remaining on the surface of the cable sheath. The multiple angled nozzles 6 are all tilted away from the tank 2 to prevent water droplets from dripping into the hollow ring 5 and reduce the contact corrosion of the hollow ring 5 by water. The hollow ring 5 is designed as a detachable module to facilitate the replacement of the hollow ring 5.

[0033] A drive motor 11 is installed at both ends of one side of the tank 2. A stirring roller 12 is fixedly installed at the output end of each of the two drive motors 11. One end of each stirring roller 12 is rotatably connected to the inner wall of the tank 2. Multiple sets of stirring rods 13 are evenly arranged on the outer side of the two stirring rollers 12. The stirring rollers 12 are installed at both ends inside the tank 2. The operation of the drive motor 11 controls the rotation of the stirring rollers 12, thereby stirring the water inside the tank 2. This avoids local overheating of the water and thus affects the water cooling effect, improving the water cooling effect of the cable sheath. Multiple support plates 14 are welded to the inner bottom of the tank 2. A second roller 15 is rotatably installed at the top center of each support plate 14. By welding multiple support plates 14 to the inner bottom of the tank 2 and rotatably installing a second roller 15 at the top center of each support plate 14, it is convenient to support the cable sheath passing through the tank 2. To prevent the cable sheath from sinking and causing wear, fixed grooves 9 are provided on both sides of the top of the trough 2. A first roller 10 is rotatably installed in the middle of the two fixed grooves 9. The fixed grooves 9 on both sides of the top of the trough 2 and the first roller 10 rotatably installed in the middle of the two fixed grooves 9 can reduce the wear of the cable sheath when passing through the trough 2. Drainage outlets 16 are provided on both sides of the inner bottom of the trough 2. Drainage pipes 17 are connected to the bottom of the two drainage outlets 16 to facilitate the drainage of water from the inside of the trough 2. A control valve 18 is fixedly installed at the output end of the drainage pipe 17 to facilitate the control of the drainage flow rate. A pair of fixing bolts 8 are installed at the connection positions of the two mounting plates 7 and the trough 2 to facilitate the replacement of the hollow ring 5.

[0034] Working principle: During assembly line operation, when the cable sheath is removed from tank 2 after water cooling, it passes through the middle of hollow ring 5. Outside air is drawn in by fan 3 at the bottom of support frame 1 and then sent into hollow ring 5 through air duct 4. The air is discharged through multiple angled nozzles 6, which blows off any water droplets remaining on the surface of the cable sheath. Furthermore, the multiple angled nozzles 6 are all tilted away from tank 2 to prevent water droplets from dripping into the hollow ring 5, reducing contact corrosion from water. The hollow ring 5 is designed as a detachable module for easy replacement. Stirring rollers 12 are installed at both ends inside the tank 2. The stirring rollers 12 are rotated by the operation of the drive motor 11, which can stir the water inside the tank 2 and avoid local overheating of the water, thus affecting the water cooling effect and improving the water cooling effect of the cable sheath. Multiple support plates 14 are welded to the bottom of the tank 2, and a second roller 15 is rotatably installed at the top center of each support plate 14, which facilitates the support of the cable sheath passing through the tank 2 during the transfer process of the cable sheath processing assembly line, and prevents the cable sheath from sinking to the bottom and causing wear.

[0035] Finally, it should be noted that the above description is only a preferred embodiment of the present utility model and is not intended to limit the present utility model. Although the present utility model has been described in detail with reference to the foregoing embodiments, those skilled in the art can still modify the technical solutions described in the foregoing embodiments or make equivalent substitutions for some of the technical features. Any modifications, equivalent substitutions, improvements, etc., made within the spirit and principles of the present utility model should be included within the protection scope of the present utility model.

Claims

1. A cooling tank for cable sheath production, comprising a tank body (2), characterized in that: A support frame (1) is welded to the bottom of the tank (2). A fan (3) is installed at one end of the support frame (1). Mounting plates (7) are installed on both sides of the top end of the tank (2). A hollow ring (5) is integrally provided at one end of the two mounting plates (7). Multiple inclined nozzles (6) are evenly arranged on the inner side of the hollow ring (5). The multiple inclined nozzles (6) are all inclined away from the tank (2). A duct (4) is provided at the air outlet end of the fan (3). The tail end of the duct (4) is threadedly connected to the bottom end of the hollow ring (5).

2. The cooling tank for cable sheath production according to claim 1, characterized in that: A drive motor (11) is installed at both ends of one side of the tank (2). A stirring roller (12) is fixedly installed at the output end of each of the two drive motors (11). One end of each of the two stirring rollers (12) is rotatably connected to the inner wall of the tank (2). Multiple sets of stirring rods (13) are evenly arranged on the outer side of the two stirring rollers (12).

3. The cooling tank for cable sheath production according to claim 1, characterized in that: The inner bottom of the tank (2) is welded with a plurality of support plates (14), and a second roller (15) is rotatably provided at the top center of each support plate (14).

4. A cooling tank for cable sheath production according to claim 1, characterized in that: The top two sides of the groove (2) are provided with fixing grooves (9), and the middle of the two fixing grooves (9) is provided with a first roller (10).

5. A cooling tank for cable sheath production according to claim 1, characterized in that: The bottom of the tank (2) is provided with drain outlets (16) on both sides, and the bottom of the two drain outlets (16) is connected to drain pipes (17).

6. A cooling tank for cable sheath production according to claim 5, characterized in that: A control valve (18) is fixedly installed at the output end of the drain pipe (17).

7. A cooling tank for cable sheath production according to claim 1, characterized in that: A pair of fixing bolts (8) are installed at the connection positions of the two mounting plates (7) and the groove (2).

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