CN111558509A

CN111558509A - Communication cable talcum powder coating device

Info

Publication number: CN111558509A
Application number: CN202010267238.6A
Authority: CN
Inventors: 不公告发明人
Original assignee: Individual
Current assignee: Wuxi Nanfang Electrotechnical Machinery Co ltd
Priority date: 2020-04-08
Filing date: 2020-04-08
Publication date: 2020-08-21
Anticipated expiration: 2040-04-08
Also published as: CN111558509B

Abstract

The invention relates to a communication cable, in particular to a communication cable talcum powder coating device. The invention aims to provide a communication cable talcum powder coating device. A communication cable talcum powder coating device comprises a support frame, a control screen, a motor, a feeding mechanism, a powder feeding cabin, a powder feeding mechanism, a residual material collecting mechanism and a discharge hole; the top of the left end of the support frame is provided with a control screen. The invention achieves the effects of stirring and finely grinding the talcum powder in advance, avoiding the phenomenon that the contact time of the talcum powder and air is too long, causing the inner agglomeration, influencing the coating quality and blocking a machine, simultaneously, leading the talcum powder to fully cover the surface of the cable by rotary powdering, preventing the talcum powder layer from generating holes, collecting redundant talcum powder in time and avoiding the talcum powder from causing carcinogenicity and harming the body health of workers.

Description

Communication cable talcum powder coating device

Technical Field

The invention relates to a communication cable, in particular to a communication cable talcum powder coating device.

Background

In the manufacturing process of the power cable, the phenomena of glue and adhesion are easy to occur between the insulated wire core and the outer sheath, and particularly the phenomena of sticking and adhesion are easy to occur when the outer sheath is extruded outside the insulated wire core or the stranded conductor through an extruder. The adhesive and the adhesion not only seriously affect the flexibility of the cable, but also affect the subsequent processing and laying installation of the cable, and can also cause the peeling difficulty of the cable, and more seriously, the adhesive and the adhesion can even cause the tearing of the insulating layer when the cable is bent, thereby reducing the service life of the cable and causing safety hazard. It is common in the industry to coat talc powder on an insulated wire core as a cable release agent to facilitate separation of the wire core from the jacket.

The prior art is a patent No. CN203103022U, which is named as a talc powder applying device for a photovoltaic cable core, and aims at the existing severe environment that a photovoltaic cable usually works at-40 ℃ to 120 ℃, so that the requirement on the adhesion between a sheath layer of the photovoltaic cable and the cable core (conductor, the same below) of the photovoltaic cable is severe, and because the photovoltaic cable is a cable type requiring easy peeling, if the surface of the cable core of the photovoltaic cable is not sprayed with talc powder as a special medium, the construction difficulty is large due to difficult peeling. However, if excessive talcum powder is sprayed on the surface of the cable core of the photovoltaic cable, the problem that the photovoltaic cable sheath layer undesirably moves relative to the cable core of the photovoltaic cable is caused, and the talcum powder box body and the powder blowing box body are attached to each other, so that the cable core of the photovoltaic cable can enter the powder blowing box body after moving out of the talcum powder box body, the talcum powder cannot shake off the terrace to cause waste and pollution, and the space occupation can be reduced by embodying the simple structure; secondly, as the powder blowing mechanism adopts the blowing quantity adjusting type powder blowing mechanism, the OD change of the cable can be responded, so that the blindness is avoided, the powder loading effect of the cable core of the photovoltaic cable is ensured, and the quality of the photovoltaic cable is finally ensured; thirdly, due to the additional arrangement of the powder stirring mechanism, the talcum powder can be uniformly attached to the surface of the cable core of the photovoltaic cable, and the whitening phenomenon cannot occur; fourthly, because the conical hopper eduction tube is arranged at the bottom of the talcum powder box body, the mode that the caked talcum powder can be introduced into the talcum powder recovery box below the talcum powder recovery box body overcomes the defect that the photovoltaic cable usually works in a severe environment of-40-120 ℃, so that the requirement on the adhesive force between the photovoltaic cable sheath layer and the photovoltaic cable core (conductor, the same below) is severe, and because the photovoltaic cable is a cable type requiring easy peeling, if the talcum powder serving as a special medium is not sprayed on the surface of the photovoltaic cable core, the construction difficulty is large due to difficult peeling. However, if excessive talcum powder is sprayed on the surface of the cable core of the photovoltaic cable, the problem that the photovoltaic cable sheath layer undesirably moves relative to the cable core of the photovoltaic cable is caused, but the talcum powder is excessively contacted with air and is agglomerated inside, so that the agglomerated talcum powder can block the device after a large amount of talcum powder enters the device, and the coating effect on the cable is poor.

And the talcum powder coating step among the prior art is usually realized by adopting a powder passing device, and the powder passing device comprises a powder box filled with talcum powder, wherein a wire rod needing to be subjected to powder is directly penetrated into one end of the powder box through the traction action of an extruder and then is penetrated out from the other end of the powder box, so that a layer of talcum powder is adhered to the surface of the wire rod. However, the talcum powder has certain adhesion and solid plasticity, when the insulated wire core passes through the talcum powder, a cavity brought out by the insulated wire core is formed in the talcum powder, and the cavity collapses under the action of gravity, so that the subsequent wire core can still be coated with the talcum powder, and the phenomenon that the powder coating effect is not good, such as non-uniformity of the talcum powder and the like, of the insulated wire core is caused.

At present, a communication cable talcum powder coating device which stirs and thins talcum powder in advance to avoid the phenomenon that the contact time of the talcum powder and air is too long to cause internal caking, influence the coating quality and block a machine, and simultaneously, the rotary powdering enables the talcum powder to fully cover the surface of a cable, so as to prevent a talcum powder layer from generating cavities, and collect redundant talcum powder in time, so as to avoid carcinogenicity of the talcum powder and harm to the health of workers, is needed to be developed, so that the problem that the contact time of the talcum powder and the air is too long and the internal caking causes the phenomenon that a large amount of talcum powder enters the device to block the device, the coating effect on the cable is poor, and the talcum powder has certain adhesion and solid plasticity, when an insulating wire core passes through the talcum powder, a cavity brought out by the insulating wire core is formed in the, the phenomenon of poor powder coating effect such as uneven talcum powder which causes the pollution of the insulated wire core.

Disclosure of Invention

The invention aims to overcome the defects that in the prior art, a large amount of talcum powder is agglomerated after entering a device due to the fact that the contact time of the talcum powder and air is too long, the coating effect on a cable is poor, and due to the fact that the talcum powder has certain adhesion and solid plasticity, when an insulating wire core passes through the talcum powder, a cavity brought out by the insulating wire core is formed in the talcum powder, the cavity is partially collapsed under the action of gravity, the powder coating effect of the talcum powder which is polluted by the insulating wire core is not uniform, and the like.

The invention is achieved by the following specific technical means:

a communication cable talcum powder coating device comprises a support frame, a control screen, a motor, a feeding mechanism, a powder feeding cabin, a powder feeding mechanism, a residual material collecting mechanism and a discharge hole; a control screen is arranged at the top of the left end of the support frame; the left part of the top end of the support frame is provided with a motor; a feeding mechanism is arranged at the right top of the support frame; a powder feeding cabin is arranged in the right middle of the supporting frame, and the left part of the top end of the powder feeding cabin is connected with the feeding mechanism; a powder feeding mechanism is arranged in the middle of the support frame, the top of the left end of the powder feeding mechanism is connected with a motor, the middle of the top of the right end of the powder feeding mechanism is connected with a material feeding mechanism, and the middle part and the right part of the powder feeding mechanism are both connected with a powder feeding cabin; a residual material collecting mechanism is arranged at the right bottom in the supporting frame, and the left part of the top end of the residual material collecting mechanism is connected with the powdering mechanism; the middle part of the bottom end of the powder feeding cabin is provided with a discharge hole.

Further, the feeding mechanism comprises a feeding pipe, a first buffer plate, a second buffer plate, a third buffer plate, a first driving wheel, an axe wheel, a first driving rod, a screen plate, a second driving wheel, a first stirring wheel, a third driving wheel, a second stirring wheel, a dryer and a material conveying port; a first buffer plate is arranged at the top of the left end in the feeding pipe; a second buffer plate is arranged in the middle of the top of the right end in the feeding pipe; a third buffer plate is arranged at the middle top part of the left end in the feeding pipe; a first driving wheel is arranged at the left bottom of the feeding pipe; a dryer is arranged at the bottom of the right end of the feeding pipe; a material conveying port is arranged at the bottom of the material feeding pipe; the axle center of the front end of the first driving wheel is rotationally connected with the axe wheel; the right part of the front end of the axe wheel is connected with the first transmission rod; the right part of the first transmission rod is connected with the screen plate; the top of the right end of the first driving wheel is in transmission connection with a second driving wheel through a belt; the axle center of the front end of the second driving wheel is rotationally connected with the first stirring wheel; the middle part of the right end of the second driving wheel is in transmission connection with a third driving wheel through a belt; the axle center of the front end of the third driving wheel is rotationally connected with the second stirring wheel; the bottom of the left end of the feeding pipe is connected with the supporting frame; the bottom end of the feeding pipe is connected with the powder feeding cabin; the rear end shaft center of the first driving wheel is connected with the supporting frame through the mounting seat; the left end of the first driving wheel is connected with the powdering mechanism.

Further, the powdering mechanism comprises a first bevel gear, a second bevel gear, a fourth driving wheel, a fifth driving wheel, a second driving rod, a cylindrical block, a sixth driving wheel, a third driving rod, a first flat gear, a second flat gear, a first telescopic rod, a third flat gear, a screw rod, a transfer block, a material storage port, a telescopic switch, a seventh driving wheel, an eighth driving wheel, a second telescopic rod, a fourth flat gear, a fifth flat gear, a first cable holder, a sixth flat gear and a second cable holder; the rear part of the right end of the first bevel gear is meshed with the second bevel gear; the axle center of the right end of the first bevel gear is rotationally connected with a seventh driving wheel; the rear end axle center of the second bevel gear is rotationally connected with a fourth transmission wheel; the middle part of the bottom end of the fourth driving wheel is in transmission connection with the fifth driving wheel through a belt; the axle center of the front end of the fifth driving wheel is rotationally connected with the second driving rod; the middle part of the bottom end of the fifth driving wheel is in transmission connection with the sixth driving wheel through a belt; a cylindrical block is arranged at the bottom of the second transmission rod; the right end axis of the cylindrical block is rotationally connected with the first flat gear; the axle center of the front end of the sixth transmission wheel is rotationally connected with the third transmission rod; the bottom end of the first flat gear is meshed with the second flat gear; the right end axle center of the second flat gear is connected with the first telescopic rod; the axle center of the right end of the first telescopic rod is connected with the third horizontal gear; the axle center of the right end of the third horizontal gear is rotationally connected with the screw rod; the transfer block is arranged at the left part of the outer surface of the screw rod; the top end of the transfer block is provided with a material storage port; a telescopic switch is arranged in the middle of the bottom end in the transfer block, and the top end of the telescopic switch is connected with the material storage port; the middle part of the bottom end of the seventh driving wheel is in transmission connection with the eighth driving wheel through a belt; the axle center of the right end of the eighth driving wheel is connected with a second telescopic rod; the right end axle center of the second telescopic rod is connected with a fourth flat gear; the top end of the fourth flat gear is meshed with the fifth flat gear; the axle center of the right end of the fifth flat gear is rotationally connected with the first cable frame; the axle center of the right end of the fifth flat gear is rotationally connected with the sixth flat gear; the left end axis of the sixth flat gear is rotationally connected with the second cable frame; the left end axis of the first bevel gear is connected with a motor; the rear end axle center of the fourth driving wheel is connected with the supporting frame through the mounting seat; the rear end axle center of the fifth driving wheel is connected with the supporting frame through a mounting seat; the left end shaft center of the cylindrical block is connected with the supporting frame through the mounting seat; the rear end axle center of the sixth driving wheel is connected with the supporting frame through the mounting seat; the right end axle center of the first flat gear is connected with the powder feeding cabin; the right middle part of the outer surface of the first telescopic rod is connected with the powdering cabin; the left part and the right part of the outer surface of the screw rod are both connected with the powdering cabin; the shaft center of the left end of the eighth transmission wheel is connected with the support frame through the mounting seat; the bottom end of the eighth driving wheel is connected with the excess material collecting mechanism; the left end of the fifth flat gear is connected with the support frame; the right end of the sixth flat gear is connected with the supporting frame.

Further, the excess material collecting mechanism comprises a ninth driving wheel, a third bevel gear, a fourth bevel gear, a tenth driving wheel, an eleventh driving wheel, a first disc, a first bump, a first driving slide rail, a first fixed seat, a first push plate, a fifth bevel gear, a sixth bevel gear, a twelfth driving wheel, a thirteenth driving wheel, a second disc, a second bump, a second driving slide rail, a second fixed seat, a second push plate and a material storage box; the axle center of the right end of the ninth transmission wheel is rotationally connected with the third bevel gear; the rear end of the third bevel gear is meshed with the fourth bevel gear; the right end axis of the third bevel gear is rotationally connected with the fifth bevel gear; the axle center at the rear end of the fourth bevel gear is rotationally connected with a tenth transmission wheel; the middle part of the top end of the tenth transmission wheel is in transmission connection with the eleventh transmission wheel through a belt; the front end axle center of the eleventh transmission wheel is rotationally connected with the first disc; a first bump is arranged at the middle top of the front end of the first disc; the left end and the right end of the first bump are connected with the first transmission slide rail; the bottom of the rear end of the first transmission slide rail is rotationally connected with the first fixed seat; the top of the rear end of the first transmission slide rail is connected with the first push plate; the rear part of the right end of the fifth bevel gear is meshed with the sixth bevel gear; the axle center at the rear end of the sixth bevel gear is rotationally connected with the twelfth driving wheel; the middle part of the top end of the twelfth driving wheel is in transmission connection with the thirteenth driving wheel through a belt; the axle center of the front end of the thirteenth driving wheel is rotationally connected with the second disc; a second lug is arranged at the middle top of the front end of the second disc; the left end and the right end of the second lug are both connected with the second transmission slide rail; the bottom of the rear end of the second transmission slide rail is rotatably connected with the second fixed seat; the top of the rear end of the second transmission slide rail is connected with the second push plate; a material storage box is arranged at the left bottom of the second push plate; the top end of the ninth transmission wheel is connected with the eighth transmission wheel; the rear end axle center of the tenth driving wheel is connected with the supporting frame through the mounting seat; the rear end axle center of the eleventh transmission wheel is connected with the supporting frame through a mounting seat; the left end of the first fixed seat is connected with the supporting frame through the mounting seat; the rear end axle center of the twelfth transmission wheel is connected with the supporting frame through the mounting seat; the shaft center at the rear end of the thirteenth driving wheel is connected with the supporting frame through the mounting seat; the right end of the second fixed seat is connected with the support frame through the mounting seat; the bottom end of the storage box is connected with the support frame.

Furthermore, the second transmission rod is matched with a groove on the surface of the cylindrical block.

Furthermore, the top end of the telescopic switch is in a triangular prism shape.

Furthermore, the motion trail of the first transmission slide rail is an arc.

Furthermore, the longitudinal section of the first push plate is trapezoidal.

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

in order to solve the problems that in the prior art, due to the fact that the contact time of talcum powder and air is too long, the interior of the talcum powder is agglomerated, a large amount of talcum powder can block a device after entering the device, the coating effect on a cable is poor, and due to the fact that the talcum powder has certain adhesion and solid plasticity, when an insulating wire core passes through the talcum powder, a cavity brought out by the insulating wire core can be formed in the talcum powder, the cavity can collapse under the action of gravity, the phenomenon that the powder coating effect is poor due to the fact that the talcum powder adhered to the insulating wire core is not uniform is caused, and the like, a feeding mechanism is designed, the prepared talcum powder is stirred and thinned through the feeding mechanism, the talcum powder is stirred and thinned in advance, the effect that the contact time of the talcum powder and the air is too long, the interior of the talcum powder is agglomerated, the coating quality is affected, and the machine is, the utility model has the advantages of reached the rotation type and gone up the powder and make the talc powder fully cover the cable surface, prevent that the talc powder layer from producing empty effect, designed clout collection mechanism, collect the unnecessary talc powder that falls through clout collection mechanism, reached and in time collected unnecessary talc powder, avoided the talc powder to have carcinogenicity harm workman healthy effect.

Drawings

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

FIG. 2 is a schematic structural diagram of a feeding mechanism according to the present invention;

FIG. 3 is a schematic structural view of a powdering mechanism according to the present invention;

fig. 4 is a schematic structural view of the remainder collecting mechanism of the present invention.

The labels in the figures are: 1-a support frame, 2-a control screen, 3-a motor, 4-a feeding mechanism, 5-a powdering cabin, 6-a powdering mechanism, 7-a remainder collecting mechanism, 8-a discharging port, 401-a feeding pipe, 402-a first buffer plate, 403-a second buffer plate, 404-a third buffer plate, 405-a first driving wheel, 406-an axe wheel, 407-a first driving rod, 408-a screen plate, 409-a second driving wheel, 4010-a first stirring wheel, 4011-a third driving wheel, 4012-a second stirring wheel, 4013-a dryer, 4014-a conveying port, 601-a first bevel gear, 602-a second bevel gear, 603-a fourth driving wheel, 604-a fifth driving wheel, 605-a second driving rod, 606-a cylindrical block, 607-a sixth driving wheel, 608-third transmission rod, 609-first flat gear, 6010-second flat gear, 6011-first telescopic rod, 6012-third flat gear, 6013-lead screw, 6014-transfer block, 6015-material storage port, 6016-telescopic switch, 6017-seventh transmission wheel, 6018-eighth transmission wheel, 6019-second telescopic rod, 6020-fourth flat gear, 6021-fifth flat gear, 6022-first cable holder, 6023-sixth flat gear, 6024-second cable holder, 701-ninth transmission wheel, 702-third bevel gear, 703-fourth bevel gear, 704-tenth transmission wheel, 705-eleventh transmission wheel, 706-first disc, 707-first bump, 708-first transmission slide rail, 709-first fixed seat, 7010-first push plate, 7011-a fifth bevel gear, 7012-a sixth bevel gear, 7013-a twelfth driving wheel, 7014-a thirteenth driving wheel, 7015-a second disk, 7016-a second bump, 7017-a second driving slide rail, 7018-a second fixed seat, 7019-a second push plate, 7020-a storage bin.

Detailed Description

The invention is further described below with reference to the figures and examples.

Examples

A communication cable talcum powder coating device is shown in figures 1-4 and comprises a support frame 1, a control screen 2, a motor 3, a feeding mechanism 4, a powder feeding cabin 5, a powder feeding mechanism 6, a surplus material collecting mechanism 7 and a discharge hole 8; a control screen 2 is arranged at the top of the left end of the support frame 1; the left part of the top end of the support frame 1 is provided with a motor 3; a feeding mechanism 4 is arranged at the right top of the support frame 1; a powder feeding cabin 5 is arranged in the right middle of the support frame 1, and the left part of the top end of the powder feeding cabin 5 is connected with the feeding mechanism 4; a powder feeding mechanism 6 is arranged in the middle of the support frame 1, the top of the left end of the powder feeding mechanism 6 is connected with the motor 3, the middle of the top of the right end of the powder feeding mechanism 6 is connected with the feeding mechanism 4, and the middle and the right of the powder feeding mechanism 6 are connected with the powder feeding cabin 5; a residual material collecting mechanism 7 is arranged at the right bottom in the supporting frame 1, and the left part of the top end of the residual material collecting mechanism 7 is connected with the powdering mechanism 6; the middle part of the bottom end of the upper powder cabin 5 is provided with a discharge hole 8.

The feeding mechanism 4 comprises a feeding pipe 401, a first buffer plate 402, a second buffer plate 403, a third buffer plate 404, a first driving wheel 405, an axe wheel 406, a first driving rod 407, a screen 408, a second driving wheel 409, a first stirring wheel 4010, a third driving wheel 4011, a second stirring wheel 4012, a dryer 4013 and a material conveying port 4014; a first buffer plate 402 is arranged at the top of the left end in the feeding pipe 401; a second buffer plate 403 is arranged in the middle of the top of the right end in the feeding pipe 401; a third buffer plate 404 is arranged at the middle top part of the left end in the feeding pipe 401; a first driving wheel 405 is arranged at the left bottom of the feeding pipe 401; a dryer 4013 is arranged at the bottom of the right end of the feeding pipe 401; a material conveying opening 4014 is formed in the bottom of the material inlet pipe 401; the front end axle center of the first driving wheel 405 is rotationally connected with the axe wheel 406; the right part of the front end of the axe wheel 406 is connected with a first transmission rod 407; the right part of the first transmission rod 407 is connected with the screen plate 408; the top of the right end of the first driving wheel 405 is in transmission connection with a second driving wheel 409 through a belt; the axle center of the front end of the second driving wheel 409 is rotationally connected with the first stirring wheel 4010; the middle part of the right end of the second driving wheel 409 is in transmission connection with a third driving wheel 4011 through a belt; the front end axle center of the third driving wheel 4011 is rotationally connected with the second stirring wheel 4012; the bottom of the left end of the feeding pipe 401 is connected with the support frame 1; the bottom end of the feeding pipe 401 is connected with the upper powder cabin 5; the rear end axle center of the first driving wheel 405 is connected with the supporting frame 1 through a mounting seat; the left end of the first driving wheel 405 is connected with the powdering mechanism 6.

The powdering mechanism 6 comprises a first bevel gear 601, a second bevel gear 602, a fourth driving wheel 603, a fifth driving wheel 604, a second driving rod 605, a cylindrical block 606, a sixth driving wheel 607, a third driving rod 608, a first flat gear 609, a second flat gear 6010, a first telescopic rod 6011, a third flat gear 6012, a screw rod 6013, a transfer block 6014, a storage port 6015, a telescopic switch 6016, a seventh driving wheel 6017, an eighth driving wheel 6018, a second telescopic rod 6019, a fourth flat gear 6020, a fifth flat gear 6021, a first cable shelf 6022, a sixth flat gear 6023 and a second cable shelf 6024; the rear part of the right end of the first bevel gear 601 is meshed with the second bevel gear 602; the right end axis of the first bevel gear 601 is rotatably connected with a seventh driving wheel 6017; the axle center of the rear end of the second bevel gear 602 is rotationally connected with the fourth transmission wheel 603; the middle part of the bottom end of the fourth driving wheel 603 is in driving connection with a fifth driving wheel 604 through a belt; the front axle center of the fifth driving wheel 604 is rotationally connected with the second driving rod 605; the middle part of the bottom end of the fifth transmission wheel 604 is in transmission connection with a sixth transmission wheel 607 through a belt; the bottom of the second transmission rod 605 is provided with a cylindrical block 606; the axle center of the right end of the cylindrical block 606 is rotationally connected with the first flat gear 609; the front axle center of the sixth transmission wheel 607 is rotationally connected with the third transmission rod 608; the bottom end of the first pinion 609 is meshed with the second pinion 6010; the right end axle center of the second flat gear 6010 is connected with the first telescopic rod 6011; the right end axle center of the first telescopic rod 6011 is connected with a third pinion 6012; the axle center of the right end of the third flat gear 6012 is rotatably connected with a screw 6013; a transfer block 6014 is arranged at the left part of the outer surface of the screw 6013; a material storage port 6015 is arranged at the top end of the transfer block 6014; a telescopic switch 6016 is arranged in the middle of the inner bottom end of the transfer block 6014, and the top end of the telescopic switch 6016 is connected with a material storage port 6015; the middle part of the bottom end of the seventh driving wheel 6017 is in transmission connection with an eighth driving wheel 6018 through a belt; the axle center of the right end of the eighth driving wheel 6018 is connected with a second telescopic rod 6019; the axle center of the right end of the second telescopic rod 6019 is connected with a fourth flat gear 6020; the top end of the fourth flat gear 6020 is meshed with the fifth flat gear 6021; the axle center of the right end of the fifth flat gear 6021 is rotatably connected with the first cable holder 6022; the axle center of the right end of the fifth flat gear 6021 is rotationally connected with the sixth flat gear 6023; the axle center of the left end of the sixth flat gear 6023 is rotatably connected with the second cable holder 6024; the left end axis of the first bevel gear 601 is connected with the motor 3; the rear end axle center of the fourth driving wheel 603 is connected with the supporting frame 1 through a mounting seat; the rear end axle center of the fifth driving wheel 604 is connected with the supporting frame 1 through a mounting seat; the left end axle center of the cylindrical block 606 is connected with the support frame 1 through the mounting seat; the rear end axle center of the sixth transmission wheel 607 is connected with the supporting frame 1 through a mounting seat; the axle center of the right end of the first flat gear 609 is connected with the upper powder cabin 5; the right middle part of the outer surface of the first telescopic rod 6011 is connected with the powdering cabin 5; the left part and the right part of the outer surface of the screw 6013 are both connected with the powdering cabin 5; the shaft center of the left end of the eighth driving wheel 6018 is connected with the support frame 1 through a mounting seat; the bottom end of the eighth driving wheel 6018 is connected with the excess material collecting mechanism 7; the left end of the fifth flat gear 6021 is connected with the support frame 1; the right end of the sixth flat gear 6023 is connected with the support frame 1.

The excess material collecting mechanism 7 comprises a ninth driving wheel 701, a third bevel gear 702, a fourth bevel gear 703, a tenth driving wheel 704, an eleventh driving wheel 705, a first disc 706, a first bump 707, a first driving slide rail 708, a first fixed seat 709, a first push plate 7010, a fifth bevel gear 7011, a sixth bevel gear 7012, a twelfth driving wheel 7013, a thirteenth driving wheel 7014, a second disc 7015, a second bump 7016, a second driving slide rail 7017, a second fixed seat 7018, a second push plate 7019 and a material storage box 7020; the axle center of the right end of the ninth transmission wheel 701 is rotatably connected with the third bevel gear 702; the rear end of the third bevel gear 702 is engaged with a fourth bevel gear 703; the right end axis of the third bevel gear 702 is rotationally connected with a fifth bevel gear 7011; the rear end axle center of the fourth bevel gear 703 is rotationally connected with a tenth transmission wheel 704; the middle part of the top end of the tenth driving wheel 704 is in driving connection with an eleventh driving wheel 705 through a belt; the front end axle center of the eleventh transmission wheel 705 is rotationally connected with the first disc 706; the middle top of the front end of the first disc 706 is provided with a first bump 707; the left end and the right end of the first bump 707 are connected with the first transmission slide rail 708; the bottom of the rear end of the first transmission slide rail 708 is rotatably connected with a first fixed seat 709; the top of the rear end of the first transmission slide rail 708 is connected with a first push plate 7010; the rear part of the right end of the fifth bevel gear 7011 is engaged with the sixth bevel gear 7012; the axis of the rear end of the sixth bevel gear 7012 is rotationally connected with a twelfth driving wheel 7013; the middle part of the top end of the twelfth driving wheel 7013 is in transmission connection with a thirteenth driving wheel 7014 through a belt; the front end axle center of the thirteenth driving wheel 7014 is rotationally connected with the second disk 7015; a second bump 7016 is arranged at the middle top of the front end of the second disk 7015; the left end and the right end of the second protrusion 7016 are both connected with a second transmission slide rail 7017; the bottom of the rear end of the second transmission slide rail 7017 is rotatably connected with a second fixed seat 7018; the top of the rear end of the second transmission slide rail 7017 is connected with a second push plate 7019; a material storage box 7020 is arranged at the left bottom of the second push plate 7019; the top end of the ninth driving wheel 701 is connected with an eighth driving wheel 6018; the rear end axle center of the tenth transmission wheel 704 is connected with the support frame 1 through a mounting seat; the rear end axle center of the eleventh transmission wheel 705 is connected with the supporting frame 1 through a mounting seat; the left end of the first fixed seat 709 is connected with the support frame 1 through a mounting seat; the rear end axle center of the twelfth driving wheel 7013 is connected with the supporting frame 1 through a mounting seat; the rear end axle center of the thirteenth driving wheel 7014 is connected with the supporting frame 1 through a mounting seat; the right end of the second fixed seat 7018 is connected with the support frame 1 through a mounting seat; the bottom end of the storage box 7020 is connected with the support frame 1.

The second drive link 605 is mated with a surface groove of the cylindrical block 606.

The top end of the telescopic switch 6016 is a triangular prism.

The motion track of the first transmission slide rail 708 is a circular arc.

The first push plate 7010 has a trapezoidal longitudinal section.

The working principle is as follows: when in use, the device is horizontally placed at a position to be used through the support frame 1, the power supply is switched on, the cable is placed on the first cable rack 6022 and the second cable rack 6024, the motor 3 is started, the prepared talcum powder is stirred and finely beaten through the feeding mechanism 4, then the talcum powder is sent into a powdering mechanism 6 in a powdering cabin 5, the talcum powder is evenly coated on the surface of the cable through the powdering mechanism 6, meanwhile, the fallen superfluous talcum powder is collected through a surplus material collecting mechanism 7, the mechanism stirs and thins the talcum powder in advance to avoid the phenomenon that the contact time of the talcum powder and air is too long to cause inner caking, influence the coating quality and block a machine, meanwhile, the talcum powder layer is fully covered on the surface of the cable by rotary powdering, so that the talcum powder layer is prevented from generating cavities, and the redundant talcum powder is collected in time, so that the talcum powder is prevented from causing carcinogenicity and harming the health of workers.

After the device is started, talcum powder is put into a material inlet pipe 401 and falls down through a first buffer plate 402, a second buffer plate 403 and a third buffer plate 404, at the moment, a first driving wheel 405 rotates to drive a second driving wheel 409 to rotate, and further drive a first stirring wheel 4010 to rotate, and further drive a third driving wheel 4011 to rotate, and further drive a second stirring wheel 4012 to rotate, the falling talcum powder is pre-dispersed through the first stirring wheel 4010 and the second stirring wheel 4012, meanwhile, the first driving wheel 405 rotates to drive an axe wheel 406 to rotate, so that the first driving wheel 407 drives a screen 408 to move left and right in the talcum powder, the talcum powder is finely sieved, the talcum powder is dried through a dryer 4013 to prevent the interior from containing water vapor, when the talcum powder needs to be used, a material conveying port is opened, the talcum powder is conveyed into a next mechanism, the mechanism is used for finely stirring the talcum powder in advance to avoid the interior agglomeration caused by the contact time of the talcum powder and the air, affecting the coating quality and clogging the machine.

After the cables are placed on the first cable shelf 6022 and the second cable shelf 6024, the first bevel gear 601 is engaged with the second bevel gear 602 to rotate, so as to drive the fourth driving wheel 603 to rotate, so as to drive the fifth driving wheel 604 to rotate, so as to drive the second driving rod 605 to rotate, so as to drive the sixth driving wheel 607 to rotate, so as to drive the third driving rod 608 to rotate, the second driving rod 605 and the third driving rod 608 slide in the groove on the surface of the cylindrical block 606, so as to drive the cylindrical block 606 to rotate in the forward and reverse directions, so as to drive the first flat gear 609 to rotate, and the first flat gear 609 is engaged with the second flat gear 6010 to rotate, at this time, the first telescopic rod 6011 is in a telescopic state, so as to drive the third flat gear 6012 to rotate, so as to drive the lead screw 6013 to rotate in the forward and reverse directions, so as to enable the transfer block 6014 to move left and right, and the movement and stop of the, when the transfer block 6014 moves to the position below the material conveying port 4014, the talcum powder is conveyed into the material storage port 6015 through the material conveying port 4014, meanwhile, the first bevel gear 601 rotates to drive the seventh driving wheel 6017 to rotate, further, the eighth driving wheel 6018 is driven to rotate, further, the fourth flat gear 6020 is driven to rotate, the fourth flat gear 6020 is meshed with the fifth flat gear 6021 to rotate, at the moment, the second telescopic rod 6019 is in a telescopic state, further, the sixth flat gear 6023 is driven to rotate, the first cable shelf 6022 and the second cable shelf 6024 drive the cable to rotate, meanwhile, the telescopic switch 6016 is opened, the transfer block 6014 moves leftwards and rightwards synchronously, the talcum powder is uniformly sprinkled on the surface of the cable, and the mechanism enables the talcum powder to fully cover the surface of the cable through rotary powdering, and prevents the talcum powder layer from generating a.

When the redundant talcum powder falls to the bottom of the powdering compartment 5, the third bevel gear 702 is driven to rotate by the rotation of the ninth driving wheel 701, the third bevel gear 702 is meshed with the fourth bevel gear 703 to rotate, the tenth driving wheel 704 is driven to rotate, the eleventh driving wheel 705 is driven to rotate, the first disc 706 is driven to rotate, the first bump 707 performs circular motion and slides in the first driving slide rail 708, the top of the first driving slide rail 708 performs reciprocating circular motion with the center of the first fixing seat 709 as the center, the first push plate 7010 moves left and right, the third bevel gear 702 rotates to drive the fifth bevel gear 7011 to rotate, the fifth bevel gear 7011 is meshed with the sixth bevel gear 7012 to rotate, the twelfth driving wheel 7013 is driven to rotate, the thirteenth driving wheel 7014 is driven to rotate, and the second disc 7015 is driven to rotate, the second bump 7016 makes circular motion and slides in the second transmission slide rail 7017 at the same time, the top of the second transmission slide rail 7017 makes reciprocating circular motion with the center of the second fixed seat 7018 as the center of a circle, the second push plate 7019 moves left and right, the residual talcum powder at the bottom of the upper powder cabin 5 is pushed to the discharge port 8 through the first push plate 7010 and the second push plate 7019, the residual talcum powder enters the storage box 7020 for collection, and the mechanism collects the residual talcum powder in time and avoids carcinogenicity of the talcum powder to harm the health of workers.

The second transmission rod 605 is matched with the surface groove of the cylindrical block 606, so that the second transmission rod 605 drives the cylindrical block 606 to rotate when the cylindrical block 606 slides in the groove.

The top end of the telescopic switch 6016 is in a triangular prism shape, so that the talcum powder is uniformly distributed after falling.

The motion track of the first transmission slide rail 708 is an arc, so that the first push plate 7010 can reciprocate to push the residual talc powder.

The first push plate 7010 has a trapezoidal longitudinal section, so that the first push plate 7010 can be more closely attached to the remainder of the talc powder.

The technical solutions of the present invention or similar technical solutions designed by those skilled in the art based on the teachings of the technical solutions of the present invention are all within the scope of the present invention to achieve the above technical effects.

Claims

1. A communication cable talcum powder coating device comprises a support frame (1), a control screen (2) and a motor (3), and is characterized by further comprising a feeding mechanism (4), a powder feeding cabin (5), a powder feeding mechanism (6), a residual material collecting mechanism (7) and a discharge hole (8); a control screen (2) is arranged at the top of the left end of the support frame (1); the left part of the top end of the support frame (1) is provided with a motor (3); a feeding mechanism (4) is arranged at the right top of the support frame (1); a powder feeding cabin (5) is arranged in the right middle of the support frame (1), and the left part of the top end of the powder feeding cabin (5) is connected with the feeding mechanism (4); a powdering mechanism (6) is arranged in the middle of the inside of the support frame (1), the top of the left end of the powdering mechanism (6) is connected with the motor (3), the middle of the top of the right end of the powdering mechanism (6) is connected with the feeding mechanism (4), and the middle and the right of the powdering mechanism (6) are both connected with the powdering cabin (5); a residual material collecting mechanism (7) is arranged at the right bottom in the supporting frame (1), and the left part of the top end of the residual material collecting mechanism (7) is connected with the powdering mechanism (6); a discharge hole (8) is arranged in the middle of the bottom end of the powder feeding cabin (5).

2. The communication cable talcum powder coating device of claim 1, wherein the feeding mechanism (4) comprises a feeding pipe (401), a first buffer plate (402), a second buffer plate (403), a third buffer plate (404), a first driving wheel (405), an axe wheel (406), a first driving rod (407), a screen plate (408), a second driving wheel (409), a first stirring wheel (4010), a third driving wheel (4011), a second stirring wheel (4012), a dryer (4013) and a material conveying port (4014); a first buffer plate (402) is arranged at the top of the left end in the feeding pipe (401); a second buffer plate (403) is arranged in the middle of the top of the right end in the feeding pipe (401); a third buffer plate (404) is arranged at the middle top part of the inner left end of the feeding pipe (401); a first driving wheel (405) is arranged at the left bottom of the feeding pipe (401); a dryer (4013) is arranged at the bottom of the right end of the feeding pipe (401); a material conveying port (4014) is formed at the bottom of the material inlet pipe (401); the front end axle center of the first driving wheel (405) is rotationally connected with the axe wheel (406); the right part of the front end of the axe wheel (406) is connected with a first transmission rod (407); the right part of the first transmission rod (407) is connected with the screen plate (408); the top of the right end of the first transmission wheel (405) is in transmission connection with a second transmission wheel (409) through a belt; the front end axle center of the second driving wheel (409) is rotationally connected with the first stirring wheel (4010); the middle part of the right end of the second driving wheel (409) is in transmission connection with a third driving wheel (4011) through a belt; the front end axle center of the third driving wheel (4011) is rotationally connected with the second stirring wheel (4012); the bottom of the left end of the feeding pipe (401) is connected with the support frame (1); the bottom end of the feeding pipe (401) is connected with the powder feeding cabin (5); the rear end axle center of the first driving wheel (405) is connected with the supporting frame (1) through a mounting seat; the left end of the first driving wheel (405) is connected with the powdering mechanism (6).

3. The communication cable talcum powder coating device according to claim 2, wherein the powdering mechanism (6) comprises a first bevel gear (601), a second bevel gear (602), a fourth transmission wheel (603), a fifth transmission wheel (604), a second transmission rod (605), a cylindrical block (606), a sixth transmission wheel (607), a third transmission rod (608), a first flat gear (609), a second flat gear (6010), a first telescopic rod (6011), a third flat gear (6012), a screw rod (6013), a transfer block (6014), a storage port (6015), a telescopic switch (6016), a seventh transmission wheel (6017), an eighth transmission wheel (6018), a second telescopic rod (6019), a fourth flat gear (6020), a fifth flat gear (6021), a first cable shelf (6022), a sixth flat gear (6023) and a second cable shelf (6024); the rear part of the right end of the first bevel gear (601) is meshed with the second bevel gear (602); the right end axle center of the first bevel gear (601) is rotationally connected with a seventh driving wheel (6017); the rear end axle center of the second bevel gear (602) is rotationally connected with a fourth transmission wheel (603); the middle part of the bottom end of the fourth transmission wheel (603) is in transmission connection with a fifth transmission wheel (604) through a belt; the front end axle center of the fifth driving wheel (604) is rotationally connected with the second driving rod (605); the middle part of the bottom end of the fifth transmission wheel (604) is in transmission connection with a sixth transmission wheel (607) through a belt; the bottom of the second transmission rod (605) is provided with a cylindrical block (606); the right end axle center of the cylindrical block (606) is rotationally connected with the first flat gear (609); the front end axle center of the sixth transmission wheel (607) is rotationally connected with the third transmission rod (608); the bottom end of the first flat gear (609) is meshed with the second flat gear (6010); the right end axle center of the second flat gear (6010) is connected with a first telescopic rod (6011); the axle center of the right end of the first telescopic rod (6011) is connected with a third horizontal gear (6012); the right end axle center of the third flat gear (6012) is rotatably connected with a screw rod (6013); a transfer block (6014) is arranged at the left part of the outer surface of the screw rod (6013); a material storage port (6015) is arranged at the top end of the transfer block (6014); a telescopic switch (6016) is arranged in the middle of the inner bottom end of the transfer block (6014), and the top end of the telescopic switch (6016) is connected with the material storage port (6015); the middle part of the bottom end of the seventh driving wheel (6017) is in transmission connection with an eighth driving wheel (6018) through a belt; the axle center of the right end of the eighth driving wheel (6018) is connected with a second telescopic rod (6019); the right end axle center of the second telescopic rod (6019) is connected with a fourth flat gear (6020); the top end of the fourth flat gear (6020) is meshed with the fifth flat gear (6021); the axle center of the right end of the fifth flat gear (6021) is rotationally connected with the first cable rack (6022); the axle center of the right end of the fifth flat gear (6021) is rotationally connected with the sixth flat gear (6023); the left end axle center of the sixth flat gear (6023) is rotationally connected with the second cable rack (6024); the left end axis of the first bevel gear (601) is connected with the motor (3); the rear end axle center of the fourth transmission wheel (603) is connected with the support frame (1) through a mounting seat; the rear end axle center of the fifth transmission wheel (604) is connected with the supporting frame (1) through a mounting seat; the left end shaft center of the cylindrical block (606) is connected with the support frame (1) through the mounting seat; the rear end axle center of the sixth transmission wheel (607) is connected with the supporting frame (1) through a mounting seat; the right end axle center of the first flat gear (609) is connected with the upper powder cabin (5); the right middle part of the outer surface of the first telescopic rod (6011) is connected with the powdering cabin (5); the left part and the right part of the outer surface of the screw rod (6013) are both connected with the powdering cabin (5); the shaft center of the left end of an eighth transmission wheel (6018) is connected with the support frame (1) through a mounting seat; the bottom end of an eighth driving wheel (6018) is connected with the excess material collecting mechanism (7); the left end of the fifth flat gear (6021) is connected with the support frame (1); the right end of the sixth flat gear (6023) is connected with the supporting frame (1).

4. The communication cable talcum powder coating device according to claim 3, wherein the surplus material collecting mechanism (7) comprises a ninth transmission wheel (701), a third bevel gear (702), a fourth bevel gear (703), a tenth transmission wheel (704), an eleventh transmission wheel (705), a first disc (706), a first bump (707), a first transmission slide rail (708), a first fixed seat (709), a first push plate (7010), a fifth bevel gear (7011), a sixth bevel gear (7012), a twelfth transmission wheel (7013), a thirteenth transmission wheel (7014), a second disc (7015), a second bump (7016), a second transmission slide rail (7017), a second fixed seat (7018), a second push plate (7019) and a storage box (7020); the right end axis of the ninth transmission wheel (701) is rotationally connected with a third bevel gear (702); the rear end of the third bevel gear (702) is meshed with the fourth bevel gear (703); the right end axis of the third bevel gear (702) is rotationally connected with a fifth bevel gear (7011); the rear end axle center of the fourth bevel gear (703) is rotationally connected with a tenth driving wheel (704); the middle part of the top end of the tenth driving wheel (704) is in transmission connection with an eleventh driving wheel (705) through a belt; the front end axle center of the eleventh transmission wheel (705) is rotationally connected with the first disc (706); a first bump (707) is arranged at the middle top of the front end of the first disc (706); the left end and the right end of the first bump (707) are connected with the first transmission slide rail (708); the bottom of the rear end of the first transmission slide rail (708) is rotatably connected with a first fixed seat (709); the top of the rear end of the first transmission slide rail (708) is connected with a first push plate (7010); the rear part of the right end of the fifth bevel gear (7011) is meshed with the sixth bevel gear (7012); the rear end axle center of the sixth bevel gear (7012) is rotationally connected with a twelfth driving wheel (7013); the middle part of the top end of the twelfth driving wheel (7013) is in transmission connection with a thirteenth driving wheel (7014) through a belt; the front end axle center of the thirteenth driving wheel (7014) is rotationally connected with the second disc (7015); a second bump (7016) is arranged at the middle top of the front end of the second disc (7015); the left end and the right end of the second bump (7016) are both connected with a second transmission slide rail (7017); the bottom of the rear end of the second transmission slide rail (7017) is rotatably connected with a second fixed seat (7018); the top of the rear end of the second transmission slide rail (7017) is connected with a second push plate (7019); a material storage box (7020) is arranged at the left bottom of the second push plate (7019); the top end of the ninth driving wheel (701) is connected with an eighth driving wheel (6018); the rear end axle center of the tenth transmission wheel (704) is connected with the support frame (1) through a mounting seat; the rear end axle center of the eleventh transmission wheel (705) is connected with the supporting frame (1) through a mounting seat; the left end of the first fixed seat (709) is connected with the support frame (1) through the mounting seat; the rear end axle center of the twelfth driving wheel (7013) is connected with the supporting frame (1) through a mounting seat; the rear end axle center of the thirteenth driving wheel (7014) is connected with the supporting frame (1) through a mounting seat; the right end of the second fixed seat (7018) is connected with the support frame (1) through a mounting seat; the bottom end of the storage box (7020) is connected with the support frame (1).

5. A talc coating apparatus for communication cable according to claim 4 wherein the second driving rod (605) is matched with the surface groove of the cylindrical block (606).

6. The talc coating apparatus for communication cable as claimed in claim 5, wherein the top of the telescopic switch (6016) is triangular prism.

7. The talc powder coating device of claim 6, wherein the motion track of the first transmission slide rail (708) is a circular arc.

8. The talc coating apparatus for telecommunication cables as in claim 7, wherein the first push plate (7010) is trapezoidal in longitudinal section.