CN114852780B - Cooling device and cooling process for cable production - Google Patents

Abstract

The invention relates to the technical field of cable production, and discloses a cooling device for cable production, which comprises a supporting device, wherein the side of the supporting device is provided with the cooling device; the device passes the processed cable through the conveying channel, then passes one end of the cable through the traction groove, and then fixes one end of the cable on the traction rod; then, the winding drum is placed on a conveying roller between the two first installation boxes, so that the winding drum can pass through the conveying hole, and one end of the winding drum is aligned to the position of the traction rod, thereby being convenient for winding the cable; the first driving motor rotates to drive the conveying roller to rotate, and the conveying roller rotates to drive the winding drum to move forwards; the second driving motor rotates to drive the driving ring to rotate, and the cable is wound on the winding drum when the driving ring rotates; before winding, opening an electromagnetic valve, and water-cooling the cable; after the winding is completed, an air cooling mechanism is started to further air-cool the cable, and cooling of the cable is completed when the winding of the cable is completed.

Description

Cooling device and cooling process for cable production

Technical Field

The invention relates to the technical field of cable production, in particular to a cooling device and a cooling process for cable production.

Background

The cable is typically a rope-like cable stranded from several wires or groups of wires (at least two in each group), each group being insulated from each other and often twisted around a center, with a highly insulating coating over the entire outer surface. The cable has an inner energized, outer insulated feature.

With the continuous expansion of the industries such as the China power industry, the data communication industry, the urban rail transit industry, the automobile industry, shipbuilding and the like, the demand for wires and cables is rapidly increased, and the wires and cables industry has great development potential in the future.

In the processing process of the cable, including cable core manufacturing and sheath manufacturing, in the manufacturing process, the cable core and the sheath are molded together, and the cable is realized through a high-temperature plastic extruding machine, so that certain cooling is required after plastic extrusion. At present, the cooling of the cable is carried out after the production is finished, and then the cable is wound and packaged, so that the production rhythm is greatly reduced.

Disclosure of Invention

In order to solve the above-mentioned shortcomings in the background art, an object of the present invention is to provide a cooling device for cable production, which comprises a supporting device, wherein a cooling device is arranged at the side of the supporting device; the device passes the processed cable through the conveying channel, then passes one end of the cable through the traction groove, and then fixes one end of the cable on the traction rod; then, the winding drum is placed on a conveying roller between the two first installation boxes, so that the winding drum can pass through the conveying hole, and one end of the winding drum is aligned to the position of the traction rod, thereby being convenient for winding the cable; the first driving motor rotates to drive the conveying roller to rotate, and the conveying roller rotates to drive the winding drum to move forwards; the second driving motor rotates to drive the driving ring to rotate, and the cable is wound on the winding drum when the driving ring rotates; before winding, opening an electromagnetic valve, and water-cooling the cable; after the winding is completed, the winding cylinder is conveyed to a conveying roller between the two second installation boxes, an air cooling mechanism is started, the cable is further cooled by air, and the cable cooling is completed when the winding of the cable is completed. According to the invention, the cooling of the cable can be realized in the process of finishing the cable processing and winding, so that the production time is greatly reduced, and the production efficiency is improved.

The aim of the invention can be achieved by the following technical scheme:

the cooling device for the cable production comprises a supporting device, wherein the cooling device is arranged at the side of the supporting device;

the supporting device comprises a supporting mechanism, and a winding mechanism is arranged on the supporting mechanism;

the cooling device comprises a water storage barrel, wherein the water storage barrel is communicated with a condenser, an electromagnetic valve is arranged between the water storage barrel and the condenser, the condenser is communicated with a hydraulic pump, the hydraulic pump is communicated with a water cooling tank, the water cooling tank is communicated with the water storage barrel, and a cable conveying channel is formed in the water cooling tank.

As a further description of the invention, the supporting mechanism comprises a supporting plate, two first installation boxes which are symmetrically distributed are arranged on one side of the supporting plate, two second installation boxes which are symmetrically distributed are arranged on the other side of the supporting plate, two air cooling mechanisms which are symmetrically distributed are arranged above the two second installation boxes, a group of conveying rollers which are distributed in an array are arranged between the two first installation boxes, two ends of each conveying roller are respectively connected with the two first installation boxes in a rotating way, a group of conveying rollers which are distributed in an array are also arranged between the two second installation boxes, and two ends of each conveying roller are respectively connected with the two second installation boxes in a rotating way.

As a further description of the invention, a mounting plate is arranged between the first mounting box and the second mounting box, a conveying hole is formed in the middle of the mounting plate, four mounting rods distributed in a circumferential array are arranged around the conveying hole, the mounting rods are rotationally connected with the mounting plate, supporting blocks are arranged on the mounting rods, supporting grooves are formed in the supporting blocks, and winding drums are arranged on the conveying rollers.

As a further description of the invention, driving rods are arranged in the first mounting box and the second mounting box, one end of each driving rod is fixedly connected with an output shaft of the first driving motor, a group of first bevel gears distributed in an array mode are arranged on each driving rod, each first bevel gear is meshed with a second bevel gear, the second bevel gears are rotatably connected with the first mounting box, the second bevel gears are rotatably connected with the second mounting box, the number of the first bevel gears and the number of the second bevel gears are equal to that of the conveying rollers, a rotating rod is arranged on one side of each second bevel gear, each rotating rod penetrates through the first mounting box and is fixedly connected with the conveying rollers, and each rotating rod penetrates through the second mounting box and is fixedly connected with the conveying rollers.

As a further description of the invention, the winding mechanism comprises a second driving motor, the second driving motor is fixed on one side of the mounting plate, four pulleys distributed in an array are arranged on the other side of the mounting plate, the four pulleys are rotationally connected with the mounting plate, belts are sleeved on the four pulleys, an output shaft of the second driving motor penetrates through the mounting plate to be fixedly connected with one of the pulleys, a traction rod is arranged on the driving ring, and a traction groove is formed in the traction rod.

As a further description of the invention, a connecting rod is arranged on each belt pulley, the connecting rod is fixedly connected with driving wheels, driving rings are arranged among the four driving wheels, the driving rings are abutted with the four driving wheels, and the driving rings are movably arranged in the supporting grooves.

A cooling process for cable production, the process comprising the steps of:

step 1: passing the processed cable through a conveying channel;

step 2: one end of the cable passes through the traction groove, and then one end of the cable is fixed on the traction rod;

step 3: the winding drum is placed on a conveying roller between the two first installation boxes, so that the winding drum can pass through the conveying hole, and one end of the winding drum is aligned to the position of the traction rod, thereby being convenient for winding cables;

step 4: starting a first driving motor, driving a driving rod to rotate through rotation of the first driving motor, driving a first bevel gear to rotate through rotation of the driving rod, driving a second bevel gear to rotate through rotation of the first bevel gear, driving a conveying roller to rotate through rotation of the second bevel gear, and driving a winding drum to move forwards through rotation of the conveying roller;

step 5: starting a second driving motor, driving one of the belt pulleys to rotate through rotation of the second driving motor, driving all the belt pulleys to rotate through a belt when one of the belt pulleys rotates, driving a driving ring to rotate through rotation of the belt pulley, and winding a cable on a winding drum when the driving ring rotates;

step 6: opening an electromagnetic valve, operating a hydraulic pump to pump out water in the water storage barrel, condensing the water by a condenser, enabling the water to enter a water cooling box, enabling the cooled water to flow in the water cooling box, cooling a cable by water, and then enabling the cooled water to flow back to the water storage barrel for recycling;

step 7: the winding drum passes through the transmission hole and then completes cable winding, meanwhile, the winding drum is conveyed to a conveying roller between two second installation boxes, an air cooling mechanism is started, the cable is further subjected to air cooling, and cable cooling is completed when the cable winding is completed.

The invention has the beneficial effects that:

the device passes the processed cable through the conveying channel, then passes one end of the cable through the traction groove, and then fixes one end of the cable on the traction rod; then, the winding drum is placed on a conveying roller between the two first installation boxes, so that the winding drum can pass through the conveying hole, and one end of the winding drum is aligned to the position of the traction rod, thereby being convenient for winding the cable; the first driving motor rotates to drive the conveying roller to rotate, and the conveying roller rotates to drive the winding drum to move forwards; the second driving motor rotates to drive the driving ring to rotate, and the cable is wound on the winding drum when the driving ring rotates; before winding, opening an electromagnetic valve, and water-cooling the cable; after the winding is completed, the winding cylinder is conveyed to a conveying roller between the two second installation boxes, an air cooling mechanism is started, the cable is further cooled by air, and the cable cooling is completed when the winding of the cable is completed. According to the invention, the cooling of the cable can be realized in the process of finishing the cable processing and winding, so that the production time is greatly reduced, and the production efficiency is improved.

Drawings

The invention is further described below with reference to the accompanying drawings.

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

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

FIG. 3 is a schematic view of the stirring mechanism of the present invention;

FIG. 4 is a schematic view of the structure of the support mechanism of the present invention;

FIG. 5 is a schematic view of a winding mechanism according to the present invention;

FIG. 6 is a schematic view of the cooling device of the present invention.

In the figure, 1, a supporting device; 2. a device; 11. a support mechanism; 12. a winding mechanism; 21. a water storage bucket; 22. a condenser; 23. a hydraulic pump; 24. a water cooling tank; 25. a cable transportation channel; 121. a second driving motor; 122. a belt pulley; 123. a belt; 124. a connecting rod; 125. a driving wheel; 126. a drive ring; 127. a traction rod; 128. a traction groove; 1101. a support plate; 1102. a first mounting box; 1103. a second mounting box; 1104. an air cooling mechanism; 1105. a conveying roller; 1106. a mounting plate; 1107. a transfer hole; 1108. a mounting rod; 1109. a support block; 1110. a support groove; 1111. winding up a winding drum; 1112. a driving rod; 1113. a first bevel gear; 1114. and a second bevel gear.

Detailed Description

The following description of the embodiments of the present invention will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present invention, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the invention without making any inventive effort, are intended to be within the scope of the invention.

In the description of the present invention, it should be understood that the terms "open," "upper," "lower," "thickness," "top," "middle," "length," "inner," "peripheral," and the like indicate orientation or positional relationships, merely for convenience in describing the present invention and to simplify the description, and do not indicate or imply that the components or elements referred to must have a particular orientation, be constructed and operated in a particular orientation, and thus should not be construed as limiting the present invention.

As shown in fig. 1, a cooling device for cable production comprises a support device 1, wherein a cooling device 2 is arranged on the side of the support device 1.

As shown in fig. 2, the supporting device 1 includes a supporting mechanism 11, and a winding mechanism 12 is disposed on the supporting mechanism 11.

As shown in fig. 3, the supporting mechanism 11 includes a supporting plate 1101, two first installation boxes 1102 that are symmetrically distributed are disposed on one side of the supporting plate 1101, two second installation boxes 1103 that are symmetrically distributed are disposed on the other side of the supporting plate 1101, two air cooling mechanisms 1104 that are symmetrically distributed are disposed above the two second installation boxes 1103, a set of conveying rollers 1105 that are distributed in an array is disposed between the two first installation boxes 1102, two ends of the conveying rollers 1105 are respectively connected with the two first installation boxes 1102 in a rotating manner, a set of conveying rollers 1105 that are distributed in an array is also disposed between the two second installation boxes 1103, and two ends of the conveying rollers 1105 are respectively connected with the two second installation boxes 1103 in a rotating manner.

The device comprises a first mounting box 1102 and a second mounting box 1103, wherein a mounting plate 1106 is arranged between the first mounting box 1102 and the second mounting box 1103, a conveying hole 1107 is formed in the middle of the mounting plate 1106, four mounting rods 1108 distributed in a circumferential array are arranged around the conveying hole 1107, the mounting rods 1108 are rotationally connected with the mounting plate 1106, a supporting block 1109 is arranged on the mounting rods 1108, a supporting groove 1110 is formed in the supporting block 1109, and a winding drum 1111 is arranged on the conveying roller 1105.

As shown in fig. 4, a driving rod 1112 is disposed in the first mounting box 1102 and the second mounting box 1103, one end of the driving rod 1112 is fixedly connected with an output shaft of a first driving motor (not shown in the drawing), a set of first bevel gears 1113 distributed in an array are disposed on the driving rod 1112, the first bevel gears 1113 are meshed with second bevel gears 1114, the second bevel gears 1114 are rotatably connected with the first mounting box 1102, the second bevel gears 1114 are rotatably connected with the second mounting box 1103, the number of the first bevel gears 1113 and the second bevel gears 1114 is equal to the number of the conveying rollers 1105, a rotating rod is disposed on one side of the second bevel gears 1114, the rotating rod penetrates through the first mounting box 1102 and is fixedly connected with the conveying rollers 1105, and the rotating rod penetrates through the second mounting box 1103 and is fixedly connected with the conveying rollers 1105.

In use, the first drive motor rotates to drive the drive rod 1112 to rotate, the drive rod 1112 rotates to drive the first bevel gear 1113 to rotate, the first bevel gear 1113 rotates to drive the second bevel gear 1114 to rotate, the second bevel gear 1114 rotates to drive the transfer roller 1105 to rotate, and the transfer roller 1105 rotates to drive the winding drum 1111 to move forwards.

As shown in fig. 5, the winding mechanism 12 includes a second driving motor 121, the second driving motor 121 is fixed on one side of a mounting plate 1106, four pulleys 122 distributed in an array are disposed on the other side of the mounting plate 1106, the four pulleys 122 are rotatably connected with the mounting plate 1106, a belt 123 is sleeved on the four pulleys 122, an output shaft of the second driving motor 121 penetrates through the mounting plate 1106 and is fixedly connected with one of the pulleys 122, a connecting rod 124 is disposed on each pulley 122, a driving wheel 125 is fixedly connected with the connecting rod 124, a driving ring 126 is disposed between the four driving wheels 125, the driving ring 126 is abutted with the four driving wheels 125, the driving ring 126 is movably disposed in a supporting groove 1110, a traction rod 127 is disposed on the driving ring 126, and a traction groove 128 is opened on the traction rod 127.

In use, one end of the cable is passed through the traction groove 128, then one end of the cable is fixed on the traction rod 127, the second driving motor 121 rotates to drive one of the belt pulleys 122 to rotate, all the belt pulleys 122 are driven to rotate by the belt when one of the belt pulleys 122 rotates, the belt pulley 122 rotates to drive the driving ring 126 to rotate, and the cable is wound on the winding drum 1111 when the driving ring 126 rotates.

As shown in fig. 6, the cooling device 2 includes a water storage tank 21, the water storage tank 21 is communicated with a condenser 22, an electromagnetic valve (not shown in the drawing) is arranged between the water storage tank 21 and the condenser 22, the condenser 22 is communicated with a hydraulic pump 23, the hydraulic pump 23 is communicated with a water cooling tank 24, the water cooling tank 24 is communicated with the water storage tank 21, and a cable conveying channel 25 is formed in the water cooling tank 24.

The cable is led to pass through the conveying channel 25, then the electromagnetic valve is opened, the hydraulic pump 23 operates to pump out the water in the water storage barrel 21, the water is condensed by the condenser 22 and then enters the water cooling box 24, the cooled water flows in the water cooling box 24 to cool the cable, and then the cable flows back to the water storage barrel 21 for recycling.

A cooling process for cable production, the process comprising the steps of:

step 1: passing the processed cable through the feed passage 25;

step 2: one end of the cable is passed through the traction groove 128, and then one end of the cable is fixed to the traction rod 127;

step 3: the winding cylinder 1111 is placed on the conveying roller 1105 between the two first installation boxes 1102, so that the winding cylinder 1111 can pass through the conveying hole 1107, and one end of the winding cylinder 1111 is aligned with the position of the traction rod 127, thereby being convenient for winding cables;

step 4: starting a first driving motor, driving a driving rod 1112 to rotate through the rotation of the first driving motor, driving the first bevel gear 1113 to rotate through the rotation of the driving rod 1112, driving a second bevel gear 1114 to rotate through the rotation of the first bevel gear 1113, driving a conveying roller 1105 to rotate through the rotation of the second bevel gear 1114, and driving a winding drum 1111 to move forwards through the rotation of the conveying roller 1105;

step 5: starting a second driving motor 121, driving one of the belt pulleys 122 to rotate through the rotation of the second driving motor 121, driving all the belt pulleys 122 to rotate through the belt when one of the belt pulleys 122 rotates, driving a driving ring 126 to rotate through the rotation of the belt pulley 122, and winding a cable on a winding drum 1111 when the driving ring 126 rotates;

step 6: the electromagnetic valve is opened, the hydraulic pump 23 operates to pump out water in the water storage barrel 21, the water enters the water cooling tank 24 after being condensed by the condenser 22, the cooled water flows in the water cooling tank 24 to cool the cable, and then flows back to the water storage barrel 21 for recycling;

step 7: the winding drum 1111 passes through the transmission hole 1107 to complete cable winding, meanwhile, the winding drum 1111 is conveyed to the conveying roller 1105 between the two second installation boxes 1103, the air cooling mechanism 1104 is started to further wind the cable, and the cable cooling is completed when the cable winding is completed.

Working principle: the device passes the processed cable through the conveying channel 25, then passes one end of the cable through the traction groove 128, and then fixes one end of the cable on the traction rod 127; then, the winding drum 1111 is placed on the conveying roller 1105 between the two first installation boxes 1102, so that the winding drum 1111 can pass through the conveying hole 1107, and one end of the winding drum 1111 is aligned to the position of the traction rod 127, thereby being convenient for winding cables; the first driving motor rotates to drive the conveying roller 1105 to rotate, and the conveying roller 1105 rotates to drive the winding drum 1111 to move forwards; the second driving motor 121 rotates to drive the driving ring 126 to rotate, and the cable is wound on the winding drum 1111 when the driving ring 126 rotates; before winding, opening an electromagnetic valve, and water-cooling the cable; after the winding is completed, the winding cylinder 1111 is conveyed to a conveying roller 1105 between the two second installation boxes 1103, the air cooling mechanism 1104 is started to further wind the cable, and the cooling of the cable is completed when the winding of the cable is completed.

In the description of the present specification, the descriptions of the terms "one embodiment," "example," "specific example," and the like, mean that a particular feature, structure, material, or characteristic described in connection with the embodiment or example is included in at least one embodiment or example of the present invention. In this specification, schematic representations of the above terms do not necessarily refer to the same embodiments or examples. Furthermore, the particular features, structures, materials, or characteristics described may be combined in any suitable manner in any one or more embodiments or examples.

The foregoing has shown and described the basic principles, principal features and advantages of the invention. It will be understood by those skilled in the art that the present invention is not limited to the embodiments described above, and that the above embodiments and descriptions are merely illustrative of the principles of the present invention, and various changes and modifications may be made without departing from the spirit and scope of the invention, which is defined in the appended claims.

Claims (4)

1. A cooling device for cable production, comprising a supporting device (1), characterized in that the side of the supporting device (1) is provided with a cooling device (2);

the supporting device (1) comprises a supporting mechanism (11), and a winding mechanism (12) is arranged on the supporting mechanism (11);

the cooling device (2) comprises a water storage barrel (21), wherein the water storage barrel (21) is communicated with a condenser (22), an electromagnetic valve is arranged between the water storage barrel (21) and the condenser (22), the condenser (22) is communicated with a hydraulic pump (23), the hydraulic pump (23) is communicated with a water cooling tank (24), the water cooling tank (24) is communicated with the water storage barrel (21), and a cable conveying channel (25) is formed in the water cooling tank (24);

the supporting mechanism (11) comprises a supporting plate (1101), two first mounting boxes (1102) which are symmetrically distributed are arranged on one side of the supporting plate (1101), two second mounting boxes (1103) which are symmetrically distributed are arranged on the other side of the supporting plate (1101), two air cooling mechanisms (1104) which are symmetrically distributed are arranged above the two second mounting boxes (1103), a group of conveying rollers (1105) which are distributed in an array are arranged between the two first mounting boxes (1102), two ends of each conveying roller (1105) are respectively connected with the two first mounting boxes (1102) in a rotating mode, a group of conveying rollers (1105) which are distributed in an array are also arranged between the two second mounting boxes (1103), and two ends of each conveying roller (1105) are respectively connected with the two second mounting boxes (1103) in a rotating mode;

the winding mechanism (12) comprises a second driving motor (121), the second driving motor (121) is fixed on one side of a mounting plate (1106), four belt pulleys (122) distributed in an array are arranged on the other side of the mounting plate (1106), the four belt pulleys (122) are rotationally connected with the mounting plate (1106), a belt (123) is sleeved on the four belt pulleys (122), an output shaft of the second driving motor (121) penetrates through the mounting plate (1106) and is fixedly connected with one of the belt pulleys (122), a traction rod (127) is arranged on a driving ring (126), and a traction groove (128) is formed in the traction rod (127);

every be equipped with connecting rod (124) on belt pulley (122), connecting rod (124) fixedly connected with drive wheel (125), four be equipped with between drive wheel (125) drive ring (126), drive ring (126) and four drive wheel (125) butt, just drive ring (126) activity sets up in supporting groove (1110).

2. The cooling device for cable production according to claim 1, wherein a mounting plate (1106) is arranged between the first mounting box (1102) and the second mounting box (1103), a conveying hole (1107) is formed in the middle of the mounting plate (1106), four mounting rods (1108) distributed in a circumferential array are arranged around the conveying hole (1107), the mounting rods (1108) are rotationally connected with the mounting plate (1106), supporting blocks (1109) are arranged on the mounting rods (1108), supporting grooves (1110) are formed in the supporting blocks (1109), and winding drums (1111) are arranged on the conveying rollers (1105).

3. A cooling device for cable production according to claim 1, characterized in that a driving rod (1112) is arranged in the first mounting box (1102) and the second mounting box (1103), one end of the driving rod (1112) is fixedly connected with the output shaft of the first driving motor, a group of first bevel gears (1113) distributed in an array are arranged on the driving rod (1112), the first bevel gears (1113) are meshed with second bevel gears (1114), the second bevel gears (1114) are rotatably connected with the first mounting box (1102), the second bevel gears (1114) are rotatably connected with the second mounting box (1103), the number of the first bevel gears (1113) and the second bevel gears (1114) is equal to the number of the conveying rollers (1105), one side of the second bevel gears (1114) is provided with a rotating rod, the rotating rod penetrates through the first mounting box (1102) and is fixedly connected with the conveying rollers (1105), and the rotating rod penetrates through the second mounting box (1103) and is fixedly connected with the conveying rollers (1105).

4. A cooling process for cable production comprising a cooling device for cable production according to any one of claims 1-3, characterized in that the process comprises the steps of:

step 1: passing the processed cable through a feed channel (25);

step 2: one end of the cable is passed through the traction groove (128), and then the cable is fixed on the traction rod (127);

step 3: placing the winding drum (1111) on a conveying roller (1105) between two first mounting boxes (1102) so that the winding drum (1111) can pass through the conveying hole (1107) and one end of the winding drum (1111) is aligned with the position of the traction rod (127), thereby being convenient for winding cables;

step 4: starting a first driving motor, driving a driving rod (1112) to rotate through rotation of the first driving motor, driving the driving rod (1112) to rotate to drive a first bevel gear (1113) to rotate, driving a second bevel gear (1114) to rotate through rotation of the first bevel gear (1113), driving a conveying roller (1105) to rotate through rotation of the second bevel gear (1114), and driving a winding drum (1111) to move forwards through rotation of the conveying roller (1105);

step 5: starting a second driving motor (121), driving one of the belt pulleys (122) to rotate through the rotation of the second driving motor (121), driving all the belt pulleys (122) to rotate through a belt when one of the belt pulleys (122) rotates, driving a driving ring (126) to rotate through the rotation of the belt pulley (122), and winding a cable on a winding drum (1111) when the driving ring (126) rotates;

step 6: opening an electromagnetic valve, operating a hydraulic pump (23) to pump out water in the water storage barrel (21), condensing the water by a condenser (22), then entering a water cooling tank (24), enabling the cooled water to flow in the water cooling tank (24), cooling a cable by water, and then flowing back to the water storage barrel (21) for recycling;

step 7: the winding drum (1111) passes through the transmission hole (1107) to finish cable winding, meanwhile, the winding drum (1111) is conveyed to a conveying roller (1105) between two second installation boxes (1103), an air cooling mechanism (1104) is started to further air-cool the cable, and cable cooling is finished when the cable winding is finished.