CN117672633A - Engineering cable processingequipment - Google Patents

Abstract

The invention discloses an engineering cable processing device, which belongs to the technical field of cable processing and comprises a cooling cylinder, wherein a ventilation cavity arranged along the length direction of the cooling cylinder is formed in the side wall of the cooling cylinder, a blowing hole is formed in the inner side wall of the cooling cylinder, clamping and supporting components are arranged at the two ends of the cooling cylinder, a rotating and rectifying component is arranged in the middle of the cooling cylinder, a driving and rotating component is communicated between an air inlet pipe and an air transmission branch pipe, and a dispersing component is arranged in one end port of the cooling cylinder; according to the invention, the clamping and supporting components at the two ends of the cooling cylinder and the rotating and rectifying component at the middle of the cooling cylinder are used for carrying out stable clamping and supporting at the two ends and the middle of the cable sheath, the surface of the cable sheath is comprehensively leveled through the rotating and rectifying component, the rotating and rectifying component is used for driving the dispersing component to rotate, and the rotating dispersing component is used for accelerating the flow rate of air flow in the cooling cylinder, so that hot air in the cooling cylinder is rapidly dispersed in time, and the cooling efficiency of the cable sheath is further improved.

Description

Engineering cable processingequipment

Technical Field

The invention relates to the technical field of cable processing, in particular to an engineering cable processing device.

Background

The cable is used as a medium for power transmission and electric energy distribution and is widely applied to aspects of control installation, connection equipment, power transmission and the like, the cable consists of a cable core and a sheath wrapped outside the cable core, the insulation sheath wraps the cable core to play a role in protection, and the quality of the outer insulation sheath directly influences the quality of the cable and the service life of the cable; at present, the production of the cable insulating sheath is directly extrusion of the insulating sheath through an extruder, and the extruder forms the outer sheath of the cable by extruding the fluid sheath raw material in a molten state, so that the freshly extruded cable insulating sheath is softer, the sheath needs to be subjected to certain cooling forming to form a finished cable, the cable is basically pulled by one end of the cable in the existing cooling mode, and then passes through a long section of water tank, and the soft sheath moves along with the pulling end in the water tank and is cooled by heat exchange with water.

Because the long section can produce insulating sheath and can take place the phenomenon that drops in the mid portion, make the insulating sheath of mid portion contact the basin bottom and lead to the fish tail insulating sheath easily, the part of dropping in the middle of the sheath can produce a pulling down to both ends simultaneously, this pulling down especially can lead to the insulating sheath at top to produce deformation and sheath wall thickness inequality to before insulating sheath cools off the design completely, lack to carry out the flattening to the rugged deformation of sheath surface and the trace of fish tail and restore, influence the finished product quality after making.

Therefore, it is necessary to provide an engineering cable processing device to solve the above technical problems.

Disclosure of Invention

The invention aims to provide an engineering cable processing device, which solves the problems that in the background technology, a sheath at the middle part is easy to drop and contact with the bottom of a water tank to scratch an insulating sheath, and meanwhile, the insulating sheath at the starting end is easy to deform, the wall thickness of the sheath is different, uneven deformation and scratch marks on the surface of the sheath are not leveled and repaired, and the quality of finished products is affected.

In order to achieve the above object, the present invention solves the above technical problems as follows: the utility model provides an engineering cable processingequipment, is open-ended cooling cylinder including both ends, the ventilation chamber has been seted up in the lateral wall of cooling cylinder, set up a plurality of blowholes with ventilation chamber intercommunication on the inside wall of cooling cylinder, the outside of cooling cylinder is provided with intake pipe and the gas transmission branch pipe to the interior transport cold air of ventilation chamber, the both ends department of cooling cylinder all is provided with the clamp support subassembly that supports the cable of wearing to send in cooling cylinder inside, the middle part of cooling cylinder is provided with the cable middle part and supports and rotate the whole subassembly of plastic to the cable surface, the intercommunication has the drive to rotate the whole subassembly between intake pipe and the gas transmission branch pipe and drives.

As a further scheme of the invention, the screwing assembly comprises a ring sleeve which is arranged in the middle of the cooling cylinder and is rotationally connected with the side wall of the cooling cylinder, a plurality of first connecting rods which are in sliding connection with the inner side surface of the ring sleeve are arranged in the ring sleeve, a first spring is sleeved on the side surface of each first connecting rod, a first arc-shaped clamping plate is fixed on one end of each first connecting rod, which is close to the center of the ring sleeve, and two ends of each first spring are respectively fixed with the inner side surface of the ring sleeve and the side surface of each first arc-shaped clamping plate.

As a further scheme of the invention, a first toothed ring is fixed on the outer side surface of the ring sleeve, a rotary seat plate is fixed on the outer side wall of the cooling cylinder, a connecting shaft rod arranged along the length direction of the cooling cylinder is rotationally connected to the rotary seat plate, an avoidance notch is formed in the side wall of the cooling cylinder, and a first gear which is positioned in the avoidance notch and is meshed and connected with the first toothed ring is fixed on the side surface of the connecting shaft rod.

As a further scheme of the invention, the rotation driving assembly comprises an outer cover shell fixed on one end side surface of the cooling cylinder, one end of the connecting shaft rod penetrates through the outer cover shell in a rotating mode, a joint sleeve is fixed on one section of the connecting shaft rod, which is located in the outer cover shell, a plurality of blades distributed in an annular mode are fixed on the side surface of the joint sleeve, the air inlet pipe and the air delivery branch pipe are communicated with the inner portion of the outer cover shell, and ports of the air inlet pipe and the air delivery branch pipe are aligned with one end, away from the joint sleeve, of the blades.

As a further scheme of the invention, the clamping and supporting assembly comprises a second connecting rod which is in sliding connection with the inner side wall of the end part of the cooling cylinder, a plurality of second connecting rods are annularly distributed, a second arc clamping plate is fixed at one end of each second connecting rod, which is close to the center of the cooling cylinder, a second spring, the two ends of which are respectively fixed with the side surface of each second arc clamping plate and the inner side wall of the cooling cylinder, is sleeved on the side surface of each second connecting rod, and one end, which is far away from the center of the cooling cylinder, of each second connecting rod extends into the ventilation cavity and is fixedly provided with a joint plate.

As a further scheme of the invention, a discharging assembly which is in transmission connection with the rotary assembly and accelerates the circulation and the discharging of hot air in the cooling cylinder is arranged in one end port of the cooling cylinder, the discharging assembly comprises a joint annular plate which is rotationally connected in one end port of the cooling cylinder far away from the outer housing, and a plurality of fan blades which are distributed in an annular shape are fixed on the inner side surface of the joint annular plate.

As a further scheme of the invention, a second toothed ring is fixed on the outer side surface of the joint ring plate, and a second gear meshed with the second toothed ring is fixed on one end of the connecting shaft rod.

As a further scheme of the invention, one end of the first arc-shaped clamping plate and one end of the second arc-shaped clamping plate, which are oriented towards each other, are respectively provided with a first inclined plane and a second inclined plane.

Compared with the prior art, the invention has the beneficial effects that:

1. the clamping and supporting components at the two ends of the cooling cylinder and the rotating and rectifying components at the middle of the cooling cylinder are used for stably clamping and supporting the cable sheath at the two ends and the middle, so that the situation that the two ends are pulled down by the falling part in the middle of the cable sheath is avoided, the deformation and the wall thickness of the cable sheath are different is avoided, the surface of the cable sheath is comprehensively leveled through the rotating and rectifying components, the leveling treatment is performed during cooling, the surface finish of the cable sheath is improved, the quality of a finished product of the cable sheath is effectively improved, and the cooling and leveling are combined into a whole, so that the whole processing efficiency of the cable sheath is effectively improved.

2. The rotating assembly drives the exhausting assembly to rotate, and the rotating exhausting assembly accelerates the flow rate of the air flow in the cooling cylinder, so that hot air absorbing heat in the cooling cylinder is pumped and discharged, the hot air in the cooling cylinder is timely and rapidly exhausted, the cold and heat exchange efficiency in the cooling cylinder is improved, and the cooling efficiency of the cable sheath is further improved.

Drawings

The invention is further illustrated by the following examples in conjunction with the accompanying drawings:

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

FIG. 2 is an enlarged view of the structure of FIG. 1 at A;

FIG. 3 is a schematic view of a partial structure of a drainage assembly according to the present invention;

FIG. 4 is a schematic view of a part of a clamping and supporting assembly according to the present invention;

FIG. 5 is an enlarged view of the structure of FIG. 4 at D;

FIG. 6 is a schematic view of the internal structure of the cooling cylinder according to the present invention;

FIG. 7 is an enlarged view of the structure at C in FIG. 6;

FIG. 8 is a schematic diagram of the internal structure of a cooling cylinder according to the present invention;

FIG. 9 is an enlarged view of the structure at B in FIG. 8;

fig. 10 is a schematic structural view of the swirling assembly and the dispersion assembly according to the present invention.

In the drawings, the list of components represented by the various numbers is as follows:

1. a spin finishing assembly; 101. a ring sleeve; 102. a first arc splint; 103. a first inclined surface; 104. a first connecting rod; 105. a first spring; 106. a first toothed ring; 107. a first gear; 108. a connecting shaft lever; 109. avoiding the notch; 110. rotating the seat plate; 2. a drive-rotation assembly; 201. an outer housing; 202. a blade; 203. a joint sleeve; 3. a drainage assembly; 301. a joint ring plate; 302. fan blades; 303. a second toothed ring; 304. a second gear; 4. a clamping and supporting assembly; 401. a second arc splint; 402. a second connecting rod; 403. a second spring; 404. a second inclined surface; 405. a joint plate; 5. a cooling cylinder; 6. a support plate; 7. a bottom plate; 8. a gas delivery branch pipe; 10. an air inlet pipe; 11. a blowing hole; 12. a ventilation chamber.

Detailed Description

The invention is further described below with reference to examples.

Referring to fig. 1-10, the invention provides an engineering cable processing device, which comprises a cooling cylinder 5, wherein two ends of the cooling cylinder 5 are arranged in an opening manner, a plurality of support plates 6 are fixed at the bottom end of the cooling cylinder 5, a bottom plate 7 is jointly fixed at the bottom ends of the plurality of support plates 6, a ventilation cavity 12 which is arranged along the length direction of the cooling cylinder 5 is formed in the side wall of the cooling cylinder 5, a plurality of air blowing holes 11 which are communicated with the ventilation cavity 12 are formed in the inner side wall of the cooling cylinder 5, the plurality of air blowing holes 11 are distributed in an equidistant manner, an air inlet pipe 10 for inputting cold air is arranged outside the cooling cylinder 5, one end of the air inlet pipe 10 is communicated with a branch pipe 8, the branch pipe 8 is communicated with the ventilation cavity 12, cold air is conveyed into the ventilation cavity 12 through the air inlet pipe 10 and the branch pipe 8, a clamping and supporting component 4 for supporting cables which are threaded in the cooling cylinder 5 is arranged at two ends of the cooling cylinder 5, a rotating whole component 1 which is used for supporting the cable middle part of the cooling cylinder 5 and shaping the cable surface is arranged in the middle part, two rotating whole components 12 which are symmetrically distributed on the two sides of the rotating whole component 1 and the rotating whole component 1 are symmetrically distributed on the inner side of the rotating whole component 1, and the rotating whole component is connected with the rotating whole component 1 and the rotating whole cooling cylinder 1 is provided with a transmission port 3 which is connected with the cooling cylinder 2; when the cooling device is used, the cable sheath penetrates through the opening end of the cooling cylinder 5 and penetrates out of the opening at the other end of the cooling cylinder 5, so that the cable sheath is conveyed and penetrated through the inside of the cooling cylinder 5, in the process, the cable sheath is stably clamped and supported at the two ends and the middle through the clamping and supporting component 4 at the two ends of the cooling cylinder 5 and the rotating and rectifying component 1 at the middle of the cooling cylinder 5, the condition that the two ends are pulled downwards by the falling part in the middle of the cable sheath, the deformation and the wall thickness of the cable sheath are different is avoided, the air inlet pipe 10 is externally connected with the air pump, the air pump is arranged at the far end of the cooling cylinder 5, the air pump pumps cold air in the external environment and conveys the air pump into the air inlet pipe 10, air flow with certain air pressure is conveyed into the air conveying branch pipe 8 through the air conveying branch pipe 8, the cold air is conveyed into the ventilation cavity 12 through the air conveying holes 11, and uniformly blown out to the cable sheath moving inside the cooling cylinder 5 in an encircling mode through the plurality of air blowing holes 11 distributed at equal intervals, and each position on the cable sheath is cooled, so that the cable sheath is cooled and cooled quickly and uniformly; in the conveying process of the air flow with certain air pressure between the air inlet pipe 10 and the air conveying branch pipe 8, the air flow drives the driving and rotating assembly 2 to work, and the driving and rotating assembly 1 is driven to synchronously rotate by the driving and rotating assembly 2, so that the surface of the cable sheath is comprehensively leveled by the rotating and rotating assembly 1 while the middle position of the cable sheath is supported by the driving and rotating assembly 1, the leveling treatment is carried out while cooling, the surface finish of the cable sheath is improved, the finished product quality of the cable sheath is effectively improved, the cooling and leveling are integrated, and the overall processing efficiency of the cable sheath is effectively improved; the heat-absorbing hot air pump is used for pumping and discharging hot air absorbed by the cooling cylinder 5, and the hot air inside the cooling cylinder 5 is timely and rapidly discharged, so that the cold-heat exchange efficiency inside the cooling cylinder 5 is improved, and the cooling efficiency of a cable sheath is further improved.

As further shown in fig. 1, 7, 9 and 10, it is worth specifically describing that the screwing assembly 1 includes a ring sleeve 101 disposed in the middle of the cooling cylinder 5 and rotationally connected to the side wall of the cooling cylinder 5 through a bearing, the inner side surface of the ring sleeve 101 is slidably connected with a first connecting rod 104, the first connecting rod 104 is provided with a plurality of first connecting rods 104 which are symmetrically distributed, the side surface of the first connecting rod 104 is sleeved with a first spring 105, two ends of the first spring 105 are respectively fixed with the inner side surface of the ring sleeve 101 and the side surface of the first arc clamping plate 102, and one end of the first connecting rod 104 close to the center of the ring sleeve 101 is fixed with the first arc clamping plate 102; during specific work, the cable sheath passes between a plurality of first arc splint 102, promote the stable centre gripping of first arc splint 102 to the cable sheath through the elasticity of first spring 105, support subassembly 4 and the stable centre gripping support of a plurality of first arc splint 102 in both ends and centre department are carried out to the cable sheath through the clamp of cooling tube 5 both ends department, avoid the part of cable sheath centre falling can produce a pulling down to both ends, the deformation and the different condition of wall thickness of cable sheath that lead to, simultaneously the synchronous drive of pivoted ring cover 101 rotates a plurality of head rods 104 and first arc splint 102, a plurality of pivoted first arc splint 102 carry out the flattening to the cable sheath surface of carrying the removal in cooling tube 5 inside, improve the finish on cable sheath surface, effectively improve the cable sheath and make finished product quality.

As further shown in fig. 3, 8 and 10, it should be specifically explained that a rotating seat board 110 is fixed on the outer side wall of the cooling cylinder 5, a connecting shaft lever 108 arranged along the length direction of the cooling cylinder 5 is rotationally connected to the rotating seat board 110, a first toothed ring 106 is fixed on the outer side surface of the ring sleeve 101, an avoidance notch 109 is formed in the side wall of the cooling cylinder 5, a first gear 107 is fixed on the middle side surface of the connecting shaft lever 108, and the first gear 107 is located in the avoidance notch 109 and is meshed with the first toothed ring 106; during specific work, the connecting shaft lever 108 is driven to rotate through the driving component 2, the connecting shaft lever 108 drives the first gear 107 to rotate, the ring sleeve 101 is driven to rotate through the cooperation of the first gear 107 and the first toothed ring 106, and therefore the plurality of first arc clamping plates 102 are driven to carry out leveling treatment while supporting the cable sheath.

As further shown in fig. 1, 3, 5 and 8, it should be noted that the rotation driving assembly 2 includes an outer casing 201 fixed on one end side of the cooling cylinder 5, a joint cover 203 is fixed on a section of the connecting shaft 108, which is rotated through the outer casing 201 and located inside the outer casing 201, a plurality of blades 202 located inside the outer casing 201 are fixed on a side of the joint cover 203, the blades 202 are distributed in a ring shape, the air inlet pipe 10 and the air delivery branch pipe 8 are symmetrically distributed on two sides of the outer casing 201, the air inlet pipe 10 and the air delivery branch pipe 8 are communicated with the inside of the outer casing 201, and the port centers of the air inlet pipe 10 and the air delivery branch pipe 8 are tangential to one end of the blades 202 away from the joint cover 203; during specific work, the air inlet pipe 10 conveys air flow with certain air pressure into the outer cover 201, the air flow pushes the blade plate 202 to rotate, the blade plate 202 and the joint sleeve 203 drive the connecting shaft rod 108 to rotate, so that the first arc clamping plate 102 is driven to rotate by utilizing the input cold air flow, an additional configuration driving source is omitted, the whole structure is simplified, the cost is reduced, the air flow in the outer cover 201 is continuously conveyed into the air conveying branch pipe 8, cold air is introduced into the ventilation cavity 12 through the air conveying branch pipe 8, and the cold air is uniformly sprayed onto the cable sheath through the plurality of air blowing holes 11, so that the heat dissipation and the temperature reduction of the cable sheath are realized.

As further shown in fig. 1, 2, 4 and 6, it should be noted that, the clamping and supporting assembly 4 includes a second connecting rod 402 slidably connected to an inner side wall of an end portion of the cooling cylinder 5, the second connecting rod 402 is provided with a plurality of second connecting rods 402 in annular distribution, one end of the second connecting rod 402 near a center of the cooling cylinder 5 is fixed with a second arc clamping plate 401, a second spring 403 is sleeved on a side surface of the second connecting rod 402, two ends of the second spring 403 are respectively fixed with a side surface of the second arc clamping plate 401 and an inner side wall of the cooling cylinder 5, and one end of the second connecting rod 402 far from the center of the cooling cylinder 5 stretches into the ventilation cavity 12 and is fixed with a joint plate 405 thereon; the cable sheath penetrates from the opening end of the cooling cylinder 5 and penetrates out from the opening at the other end of the cooling cylinder 5, the cable sheath penetrates between a plurality of second arc clamping plates 401 at the ports at the two ends of the cooling cylinder 5, the second arc clamping plates 401 are pushed to stably clamp the cable sheath through the elastic force of the second springs 403, and therefore the cable sheath is stably clamped and supported at the two ends and the middle through the second arc clamping plates 401 at the two ends of the cooling cylinder 5 and the first arc clamping plates 102 in the middle of the cooling cylinder 5.

As further shown in fig. 3, 4, 6, 8 and 10, it should be noted that the dissipation assembly 3 includes a joint ring plate 301 rotatably connected to an end port of the cooling cylinder 5 far from the outer casing 201, and a plurality of fan blades 302 distributed in a ring shape are fixed on an inner side surface of the joint ring plate 301; during specific work, through driving joint annular plate 301 to rotate, the rotating joint annular plate 301 drives a plurality of fan blades 302 to rotate, a plurality of rotating fan blades 302 push the inside gas of cooling cylinder 5, fan blades 302 accelerate the flow rate of the inside air current of cooling cylinder 5 to form and pump out the inside hot air that absorbs heat of cooling cylinder 5, in time quick the exhaust of hot air inside cooling cylinder 5, thereby improve cooling cylinder 5 inside cold and heat exchange efficiency, and then improve the cooling efficiency of cable sheath.

As further shown in fig. 6, 8 and 10, it should be specifically explained that the second toothed ring 303 is fixed on the outer side surface of the joint ring plate 301, and the second gear 304 engaged with the second toothed ring 303 is fixed on one end of the connecting shaft 108; in specific operation, the second gear 304 is driven to rotate by the connecting shaft 108, and the joint ring plate 301 is driven to rotate by the cooperation of the second gear 304 and the second toothed ring 303, so that the ring sleeve 101 and the joint ring plate 301 form linkage driving.

The scheme comprises the following working processes: the cable sheath penetrates from the opening end of the cooling cylinder 5 and penetrates out from the opening at the other end of the cooling cylinder 5, the cable sheath penetrates between a plurality of second arc clamping plates 401 at the two end ports of the cooling cylinder 5, the second arc clamping plates 401 are pushed to clamp the cable sheath by the elastic force of the second springs 403, meanwhile, the cable sheath penetrates between a plurality of first arc clamping plates 102, the first arc clamping plates 102 are pushed to stably clamp the cable sheath by the elastic force of the first springs 105, and therefore the cable sheath is stably clamped and supported at the two ends and the middle through the second arc clamping plates 401 and the first arc clamping plates 102; the air flow with certain air pressure is conveyed into the air conveying branch pipe 8 through the air conveying branch pipe 8, cold air is conveyed into the ventilation cavity 12 through the air conveying branch pipe 8, the air blowing holes 11 distributed at equal intervals are formed in a surrounding mode and evenly blown out of the cable sheath moving inside the cooling cylinder 5, heat dissipation and cooling are carried out on the cable sheath, in the air conveying process, the air flow with certain air pressure is conveyed into the outer cover 201 through the air inlet pipe 10, the blade plate 202 is pushed to rotate through the air flow, the connecting shaft rod 108 is driven to rotate through the blade plate 202 and the joint sleeve 203, the connecting shaft rod 108 drives the first gear 107 to rotate, the rotating annular sleeve 101 synchronously drives the plurality of first connecting rods 104 and the first arc clamping plates 102 to rotate, the plurality of rotating first arc clamping plates 102 simultaneously level the surface of the cable sheath moving inside the cooling cylinder 5, the second gear 304 is driven to rotate through the connecting shaft rod 108, the second gear 304 and the second toothed ring plate 301 is driven to rotate through the cooperation of the second gear 304 and the second toothed ring 303, the blade plate 302 is driven to rotate, the air flow inside the cooling cylinder 302 is cooled, and the air flow inside the fan blade plate 302 is cooled, and the air flow inside the cooling cylinder 5 is cooled, and the heat is cooled, and the fan blade plate 302 is cooled, and the inside the fan blade plate 302 is cooled, and the fan blade plate 302 is driven to flow and the inside the cooling cylinder is cooled, and the inside the fan air flow is cooled, and the inside and the fan air is cooled, and the inside and the air is cooled.

As further shown in fig. 2, 7 and 10, it should be specifically noted that the first inclined surface 103 and the second inclined surface 404 are respectively disposed on the same facing ends of the first arc clamping plate 102 and the second arc clamping plate 401; during specific work, the cable sheath is conveniently inserted between the plurality of second arc clamping plates 401 and the first arc clamping plates 102 through the first inclined plane 103 and the first connecting rod 104, so that the cable sheath is convenient and practical.

To sum up: the clamping and supporting components 4 at the two ends of the cooling cylinder 5 and the rotary whole component 1 in the middle of the cooling cylinder 5 are used for carrying out stable clamping and supporting at the two ends and the middle, so that the situation that the two ends of the cable sheath are deformed and the wall thickness is different due to the fact that a part of the cable sheath which is dropped down in the middle can generate a downward pulling force is avoided, an air inlet pipe 10 is externally connected with an air pump, the air pump is arranged at the far distance of the cooling cylinder 5, cold air in the external environment is pumped by the air pump and is conveyed into the air inlet pipe 10, air flow with certain air pressure is conveyed into the air conveying branch pipe 8 through the air inlet pipe 10, the cold air is conveyed into the ventilation cavity 12 through the air conveying branch pipe 8, and is uniformly blown out to the cable sheath moving in the cooling cylinder 5 in an encircling mode through a plurality of blowing holes 11 which are distributed at equal intervals, and each position on the cable sheath is subjected to heat dissipation and cooling, and rapid uniform heat dissipation and cooling are carried out on the cable sheath; in the conveying process of the air flow with certain air pressure between the air inlet pipe 10 and the air conveying branch pipe 8, the air flow drives the driving and rotating assembly 2 to drive the rotating and rectifying assembly 1 to synchronously rotate, so that the surface of the cable sheath is comprehensively leveled through the rotating and rectifying assembly 1 while the middle position of the cable sheath is supported by the rotating and rectifying assembly 1, the surface of the cable sheath is leveled while being cooled, the finish degree of the surface of the cable sheath is improved, the quality of finished products of the cable sheath is effectively improved, the cooling and leveling are integrated, and the overall processing efficiency of the cable sheath is effectively improved; the heat-absorbing hot air pump is used for pumping and discharging hot air absorbed by the cooling cylinder 5, and the hot air inside the cooling cylinder 5 is timely and rapidly discharged, so that the cold-heat exchange efficiency inside the cooling cylinder 5 is improved, and the cooling efficiency of a cable sheath is further improved.

The air pump can be purchased in the market, is provided with a power supply, is well known in the art, and is not repeated in the specification.

Claims (8)

1. The utility model provides an engineering cable processingequipment, is including both ends and is open-ended cooling cylinder, its characterized in that, the ventilation chamber has been seted up in the lateral wall of cooling cylinder, set up a plurality of blowholes with ventilation chamber intercommunication on the inside wall of cooling cylinder, the outside of cooling cylinder is provided with intake pipe and the gas transmission branch pipe to the intraductal cold air that carries of ventilation, the both ends department of cooling cylinder all is provided with the clamp that supports the cable of wearing to send in cooling cylinder and props the subassembly, the middle part of cooling cylinder is provided with the cable middle part and supports and rotate the whole subassembly of plastic on the cable surface, the intercommunication has the drive to rotating the whole subassembly between intake pipe and the gas transmission branch pipe and drives.

2. The engineering cable processing device according to claim 1, wherein the screwing assembly comprises a ring sleeve which is arranged in the middle of the cooling cylinder and is rotationally connected with the side wall of the cooling cylinder, a plurality of first connecting rods which are slidably connected with the inner side surface of the ring sleeve are arranged in the ring sleeve, a first spring is sleeved on the side surface of each first connecting rod, a first arc-shaped clamping plate is fixed on one end, close to the center of the ring sleeve, of each first connecting rod, and two ends of each first spring are respectively fixed with the inner side surface of the ring sleeve and the side surface of each first arc-shaped clamping plate.

3. The engineering cable processing device according to claim 2, wherein a first toothed ring is fixed on the outer side face of the ring sleeve, a rotating seat plate is fixed on the outer side wall of the cooling cylinder, a connecting shaft rod arranged along the length direction of the cooling cylinder is rotationally connected to the rotating seat plate, an avoidance notch is formed in the side wall of the cooling cylinder, and a first gear which is positioned in the avoidance notch and meshed with the first toothed ring is fixed on the side face of the connecting shaft rod.

4. The engineering cable processing device according to claim 3, wherein the rotation driving assembly comprises an outer cover shell fixed on one end side surface of the cooling cylinder, one end of the connecting shaft rod penetrates through the outer cover shell in a rotating mode, a joint sleeve is fixed on one section of the connecting shaft rod, located inside the outer cover shell, a plurality of blades distributed in an annular mode are fixed on the side surface of the joint sleeve, the air inlet pipe and the air delivery branch pipe are communicated with the inner portion of the outer cover shell, and ports of the air inlet pipe and the air delivery branch pipe are aligned with one end, away from the joint sleeve, of the blades.

5. The engineering cable processing device according to claim 1, wherein the clamping and supporting assembly comprises a second connecting rod which is slidably connected with the inner side wall of the end part of the cooling cylinder, a plurality of second connecting rods are annularly distributed, a second arc clamping plate is fixed on one end, close to the center of the cooling cylinder, of each second connecting rod, a second spring with two ends fixed with the side surface of the second arc clamping plate and the inner side wall of the cooling cylinder respectively is sleeved on the side surface of each second connecting rod, and one end, far away from the center of the cooling cylinder, of each second connecting rod extends into the ventilation cavity and is fixedly provided with a joint plate.

6. The engineering cable processing device according to claim 4, wherein a dissipation assembly which is in transmission connection with the screwing assembly and accelerates the circulation and dissipation of hot air in the cooling cylinder is arranged in one end port of the cooling cylinder, the dissipation assembly comprises a joint ring plate which is rotatably connected in one end port of the cooling cylinder far away from the outer housing, and a plurality of fan blades which are distributed in a ring shape are fixed on the inner side surface of the joint ring plate.

7. The engineering cable processing device of claim 6, wherein a second toothed ring is fixed on the outer side surface of the joint ring plate, and a second gear engaged with the second toothed ring is fixed on one end of the connecting shaft rod.

8. The engineering cable processing device of claim 7, wherein the first arc clamping plate and the second arc clamping plate are provided with a first inclined plane and a second inclined plane respectively on one end facing the same direction.