CN111244721B

CN111244721B - 2-core or 3-core wire rod penetrating and drying heat-shrinking sleeve equipment

Info

Publication number: CN111244721B
Application number: CN202010189751.8A
Authority: CN
Inventors: 王红生; 何德良
Original assignee: Shenzhen Youji Intelligent Technology Co ltd
Current assignee: Shenzhen Youji Intelligent Technology Co ltd
Priority date: 2020-03-17
Filing date: 2020-03-17
Publication date: 2024-04-16
Anticipated expiration: 2040-03-17
Also published as: CN111244721A

Abstract

The invention discloses a 2-core or 3-core wire riveting terminal and a penetrating and drying heat shrinking sleeve device, which comprises a mounting plate, a plurality of groups of linearly connected slideway carrying mechanisms, a multi-component wire mechanism, a wire stripping mechanism and the like, wherein the slideway carrying mechanisms are arranged on the mounting plate; the carrier lifting mechanisms are respectively arranged at two ends of the mounting plate, which correspond to the slideway carrying mechanisms, carrier reflux mechanisms are arranged below the mounting plate, and two ends of the carrier reflux mechanisms correspond to the two carrier lifting mechanisms respectively. The technical scheme of the invention aims at realizing the equipment for integrally operating the riveting terminal, penetrating the heat-shrinkable sleeve and drying the heat-shrinkable sleeve, improving the production efficiency and reducing the production cost.

Description

2-core or 3-core wire rod penetrating and drying heat-shrinking sleeve equipment

Technical Field

The invention relates to the technical field of wire production and processing, in particular to a 2-core or 3-core wire penetrating and drying heat-shrinking sleeve device.

Background

With the development of modern electronic technology, the demand of wires is greatly increased, and the production efficiency is required to be improved and the production cost is reduced because the production cost is greatly increased for manufacturers. The existing technology of riveting and perforating and baking the tail end of the 2-core or 3-core wire material mainly comprises the steps of firstly shearing and peeling the rear core wire, then riveting and pressing the terminal by riveting and pressing equipment, and then perforating and baking the heat-shrinkable sleeve, wherein the technology is divided into three operations, and all the three operations need personnel, so that the whole operation flow needs a plurality of people to operate, and the efficiency is low.

Disclosure of Invention

The invention mainly aims at providing equipment for penetrating and drying heat-shrinkable sleeves through 2-core or 3-core wires, which aims to realize the integrated operation of riveting terminals, penetrating heat-shrinkable sleeves and drying the heat-shrinkable sleeves, improve the production efficiency and reduce the production cost.

In order to achieve the above purpose, the invention relates to a 2-core or 3-core wire rod penetrating and drying heat shrinking sleeve device, which comprises a mounting plate and a plurality of groups of linearly connected slide carrying mechanisms arranged on the mounting plate, wherein each slide carrying mechanism comprises two parallel slide groove tracks, a poking cylinder, a plurality of carrier sliding blocks, linear sliding rails and a pushing plate, the bottoms of the two slide groove tracks are respectively provided with a support column group, the carrier sliding blocks are slidably arranged on the slide groove tracks, each carrier sliding block is provided with a carrier, the poking cylinder is parallel to the slide groove tracks and is arranged on the support column groups, the linear sliding rails are slidably arranged on the support column groups, the pushing plate is arranged at one end of the linear sliding rail, and the output end of the poking cylinder is connected with the pushing plate; an elastic toggle block is arranged at the position, corresponding to each carrier sliding block, on the linear sliding rail; carrier lifting mechanisms are respectively arranged at two ends of the mounting plate, which correspond to the slideway carrying mechanisms, carrier reflux mechanisms are arranged below the mounting plate, and two ends of the carrier reflux mechanisms correspond to the two carrier lifting mechanisms respectively; the multi-group slide carrying mechanism comprises a first branching mechanism, a first core wire stripping mechanism, a first riveting mechanism, a first heat-shrinkable sleeve mechanism, a first core wire replacing mechanism, a second core wire stripping mechanism, a second riveting mechanism, a second heat-shrinkable sleeve, a second core wire replacing mechanism, a third core wire stripping mechanism, a third riveting mechanism, a third heat-shrinkable sleeve machine, a straightening mechanism, an oven and a wire taking mechanism, wherein the first core wire stripping mechanism, the second core wire stripping mechanism and the third core wire stripping mechanism are consistent in structure, the first riveting mechanism, the second riveting mechanism and the third riveting mechanism are consistent in structure, the first heat-shrinkable sleeve mechanism, the second heat-shrinkable sleeve mechanism and the third heat-shrinkable sleeve mechanism are consistent in structure, and the first core wire stripping mechanism and the second core wire stripping mechanism are consistent in structure.

Preferably, the mounting plate is provided with a cylinder mounting frame, and the cylinder mounting frame is corresponding to the first branching mechanism, the first core wire stripping mechanism, the first heat-shrinkable sleeve mechanism, the first core wire replacing mechanism, the second core wire stripping mechanism, the second heat-shrinkable sleeve, the second core wire replacing mechanism, the third core wire stripping mechanism, the third heat-shrinkable sleeve machine and the straightening mechanism are respectively provided with a wire pressing cylinder.

Preferably, the cylinder mounting frame is provided with rail lifting cylinders at positions corresponding to the first riveting mechanism, the second riveting mechanism and the third riveting mechanism, lifting rails and guide column groups for lifting the lifting rails are arranged below the rail lifting cylinders, and the rail lifting cylinders are in driving connection with the guide column groups.

Preferably, each carrier lifting mechanism comprises a support plate, an upper limit plate, a lifting linear guide rail, a chute fixing plate, a lifting chute, a chute lifting cylinder and a lower limit plate, wherein the support plate is vertically arranged on the mounting plate in a penetrating mode, the lifting linear guide rail is arranged on the support plate along the vertical direction, the upper limit plate and the lower limit plate are arranged at two ends of the lifting linear guide rail, the chute fixing plate is slidably arranged on the lifting linear guide rail, the lifting chute is arranged on the chute fixing plate, and one end of the chute fixing plate is connected with the chute lifting cylinder.

Preferably, the carrier reflux mechanism comprises a reflux belt, a belt fixing frame and two carrier driving components, wherein the reflux belt is arranged at the bottom of the mounting plate in parallel through the belt fixing frame, two ends of the reflux belt correspond to the two carrier lifting mechanisms respectively, and the two carrier driving components are arranged at the side edges of two ends of the reflux belt; each carrier driving assembly comprises a transverse moving air cylinder, a telescopic air cylinder and a carrier pulling rod, wherein the telescopic air cylinder is arranged at the driving end of the transverse moving air cylinder, and the carrier pulling rod is arranged at the driving end of the telescopic air cylinder.

Preferably, the first branching mechanism comprises a branching block, a branching block fixing plate, a front cylinder fixing plate, a rear cylinder fixing plate, a front cylinder, a rear cylinder, a fixing bottom plate, a sliding plate, a branching sliding rail, a branching lifting cylinder and a branching cylinder fixing plate; the fixed baseplate is arranged on the mounting plate, the branching sliding rail is arranged on the fixed baseplate along the direction perpendicular to the sliding groove track, the branching cylinder fixing plate is arranged on the branching sliding rail in a sliding way, the branching lifting cylinder is arranged on the branching cylinder fixing plate, the branching block fixing plate is arranged at the output end of the branching lifting cylinder, the branching block is arranged on the branching block fixing plate, the front and rear cylinders are arranged on one side of the fixed baseplate through the front and rear cylinder fixing plates, and the driving direction of the front and rear cylinders is parallel to the branching sliding rail.

The technical scheme of the invention has the advantages that the operations of cutting, peeling, riveting the terminal and sleeving and baking the heat-shrinking sleeve of each core wire are automatically completed, the operations of different lengths of each core wire and different specifications and lengths of each core wire can be realized, so that the invention can be compatible with more operations of products with different requirements, the operation efficiency and the product quality can be improved, and the production cost can be reduced.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings that are required in the embodiments or the description of the prior art will be briefly described, and it is obvious that the drawings in the following description are only some embodiments of the present invention, and other drawings may be obtained according to the structures shown in these drawings without inventive effort for a person skilled in the art.

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

FIG. 2 is a schematic diagram of a connection structure of a plurality of sets of slide carriers according to the present invention;

FIG. 3 is an enlarged schematic view of the structure at M in FIG. 2;

fig. 4 is an enlarged schematic view of the structure at N in fig. 2;

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

FIG. 6 is a schematic diagram of a reflow mechanism of a carrier according to the present invention;

FIG. 7 is a schematic view of a first branching mechanism according to the present invention;

FIG. 8 is a schematic structural view of a first core stripping mechanism according to the present invention;

FIG. 9 is a schematic structural view of a first riveting mechanism according to the present invention;

FIG. 10 is a schematic view of the alignment mechanism of the present invention;

the achievement of the objects, functional features and advantages of the present invention will be further described with reference to the accompanying drawings, in conjunction with the embodiments.

Detailed Description

As shown in fig. 1-4, a 2-core or 3-core wire rod heat-shrinking sleeve penetrating device according to the present embodiment includes a mounting plate 1000 and a plurality of groups of linearly connected slide carrying mechanisms 2000 disposed on the mounting plate 1000, each slide carrying mechanism 2000 includes two parallel slide rails 2010, a toggle cylinder 2011, a plurality of carrier sliders 2012, linear slide rails 2013 and a push plate 2014, support column groups 2016 are disposed at the bottoms of the two slide rails 2010 respectively, the carrier sliders 2012 are slidably disposed on the slide rails 2010, carriers 2015 are disposed on each carrier slider 2012, the toggle cylinders 2011 are parallel to the slide rails 2016 and are disposed on the support column groups, the push plate 2014 is slidably disposed on the support column groups 2016, the push plate 2014 is disposed at one end of the linear slide rails 2013, and the output end of the toggle cylinder 2011 is connected with the push plate 2014; an elastic poking block 2017 is arranged on the linear slide rail 2013 corresponding to the position of each carrier sliding block 2012; carrier lifting mechanisms 3000 are respectively arranged at two ends of the mounting plate 1000 corresponding to the slideway carrying mechanisms 2000, a carrier reflux mechanism 4000 is arranged below the mounting plate 1000, and two ends of the carrier reflux mechanism 4000 correspond to the two carrier lifting mechanisms 3000 respectively; one side of the multi-group slide carrying mechanism 2000 is sequentially provided with a first branching mechanism 5100, a first core stripping mechanism 6100, a first riveting mechanism 7100, a first set of heat-shrinkable sleeve mechanism 8100, a first core replacing mechanism 9100, a second core stripping mechanism 6200, a second riveting mechanism 7200, a second set of heat-shrinkable sleeve 8200, a second core replacing mechanism 9200, a third core stripping mechanism 6300, a third riveting mechanism 7300, a third set of heat-shrinkable sleeve mechanism 8300, a straightening mechanism 9300, an oven 1100 and a wire taking mechanism 1200, the first core stripping mechanism 6100, the second core stripping mechanism 6200 and the third core stripping mechanism 6300 are consistent in structure, the first riveting mechanism 7100, the second riveting mechanism 7200 and the third riveting mechanism 7300 are consistent in structure, the first set of heat-shrinkable sleeve mechanism 8100, the second set of heat-shrinkable sleeve 8200 and the third set of heat-shrinkable sleeve mechanism 8300 are consistent in structure, and the first core stripping mechanism 6100 and the second core stripping mechanism 6200 are consistent in structure.

In an embodiment of the present invention, as shown in fig. 4, the mounting plate 1000 is provided with a cylinder mounting frame 1300, and the cylinder mounting frame 1300 is provided with a wire pressing cylinder 1310 at positions corresponding to the first wire separating mechanism 5100, the first wire stripping mechanism 6100, the first heat shrinkage bush mechanism 8100, the first wire exchanging mechanism 9100, the second wire stripping mechanism 6200, the second heat shrinkage bush mechanism 8200, the second wire exchanging mechanism 9200, the third wire stripping mechanism 6300, the third heat shrinkage bush mechanism 8300 and the wire straightening mechanism 9300.

In an embodiment of the present invention, as shown in fig. 4, a rail lifting cylinder 1320 is disposed on the cylinder mounting frame 1300 at positions corresponding to the first riveting mechanism 7100, the second riveting mechanism 7200 and the third riveting mechanism 7300, a lifting rail 1330 and a guide post set 1340 for lifting the lifting rail 1330 are disposed below the rail lifting cylinder 1320, and the rail lifting cylinder 1320 is in driving connection with the guide post set 1340; the lifting rail 1330 may be a corresponding chute rail 2010, which is configured to be movable up and down, and supported by a wire column set 1340.

In an embodiment of the present invention, as shown in fig. 5, each carrier lifting mechanism 3000 includes a support plate 3100, an upper limiting plate 3200, a lifting linear guide 3300, a chute fixing plate 3400, a lifting chute 3500, a chute lifting cylinder 3600 and a lower limiting plate 3700, wherein the support plate 3100 is vertically penetrating through the mounting plate 1000, the lifting linear guide 3300 is vertically disposed on the support plate 3100, the upper limiting plate 3200 and the lower limiting plate 3700 are disposed at two ends of the lifting linear guide 3300, the chute fixing plate 3400 is slidably disposed on the lifting linear guide 3300, the lifting chute 3500 is disposed on the chute fixing plate 3400, and one end of the chute fixing plate 3400 is connected with the chute lifting cylinder 3600.

In an embodiment of the present invention, as shown in fig. 6, the carrier reflow mechanism 4000 includes a reflow belt 4100, a belt fixing frame 4200, and two carrier driving components, wherein the reflow belt 4100 is disposed at the bottom of the mounting board 1000 in parallel through the belt fixing frame 4200, two ends of the reflow belt 4100 respectively correspond to the two carrier lifting mechanisms 3000, and the two carrier driving components are disposed at sides of two ends of the reflow belt 4100; each carrier driving assembly comprises a traversing cylinder 4310, a telescopic cylinder 4320 and a carrier pulling rod 4330, wherein the telescopic cylinder 4320 is arranged at the driving end of the traversing cylinder 4310, and the carrier pulling rod 4330 is arranged at the driving end of the telescopic cylinder 4320; the return belt 4100 is driven 4400 by a variable speed motor.

In one embodiment of the present invention, as shown in fig. 7, the first branching mechanism 5100 includes a branching block 5110, a branching block fixing plate 5120, a front and rear cylinder fixing plate 5130, a front and rear cylinder 5140, a fixing base plate 5150, a sliding plate 5160, a branching slide rail 5170, a branching lifting cylinder 5180 and a branching cylinder fixing plate 5190; the fixed bottom plate 5150 is arranged on the mounting plate 1000, the branching sliding rail 5170 is arranged on the fixed bottom plate 5150 along the direction perpendicular to the sliding groove track 2010, the branching cylinder fixing plate 5190 is arranged on the branching sliding rail 5170 in a sliding manner, the branching lifting cylinder 5180 is arranged on the branching cylinder fixing plate 5190, the branching block fixing plate 5120 is arranged at the output end of the branching lifting cylinder 5180, the branching block 5110 is arranged on the branching block fixing plate 5120, the front and rear cylinders 5140 are arranged on one side of the fixed bottom plate 5150 through the front and rear cylinder 5140 fixing plates 5130, and the driving direction of the front and rear cylinders 5140 is parallel to the branching sliding rail 5170.

As shown in fig. 8, the first core stripping mechanism 6100 includes an opening and closing cylinder 6101, an upper blade frame 6102, an upper blade frame rack 6103, a waste suction pipe 6104, a transmission gear 6105, a vertical support plate 6106, a lower blade frame rack 6107, an upper stripping blade group 6108, a vertical linear guide 6109, a lower stripping blade group 6110, a lower blade frame 6111, a first core stripping front and rear cylinder 6112, a second core stripping front and rear cylinder 6113, a first core stripping fixed plate 6114, a first core stripping bottom plate 6115, a second core stripping fixed plate 6116, a front and rear sliding plate 6117, and a front and rear linear guide 6118; action one: the first core stripping front-back cylinder 5140 and the first core stripping front-back cylinder 6112 extend to enable the upper stripping cutter group 6108 and the lower stripping cutter group 6110 to move forwards to the core stripping position; action two: the opening and closing cylinder 6101 presses the upper knife rest 6102 to enable the upper knife rest 6108 to downwards tangential the core wire, and simultaneously enables the lower knife rest 6110 to upwards tangential the core wire through the upper knife rest rack 6103, the transmission gear 6105, the lower knife rest rack 6107 and the lower knife rest 6111; and action III: the first core stripping front and back cylinder 6112 pulls backwards to realize half peeling and pulling; and action four: the opening and closing cylinder 6101 retreats to open the upper stripping cutter group 6108 and the lower stripping cutter group 6110; action five: the second core stripping front and back cylinder 5140 is pulled back to complete the core stripping operation.

As shown in fig. 9, the first riveting mechanism 7100 includes a terminal riveting press 7101, a riveting press die 7102, a riveting front and rear cylinder 7103, a riveting front and rear cylinder fixing plate 7104, a slidable terminal machine fixing plate 7105, a riveting advance stopper 7106, a riveting bottom plate 7107, a terminal guide groove 7108, a press-riveting linear guide rail 7109, and a terminal plate 7110; action one: the riveting front and back air cylinders 7103 push the terminal riveting machine 7101, the riveting die 7102, the terminal guide groove 7108 and the terminal disc 7110 to the riveting position by pushing the slidable terminal machine fixing plate 7105; action two: after the wire on the carrier 2015 of the riveting process is pressed down to a proper position by the rail lifting cylinder 1320 in fig. 4; and action III: the terminal riveting machine 7101 starts riveting, and the riveting die 7102 rivets the terminal on the wire core wire; and action four: the rail lifting cylinder 1320 in fig. 2 returns the upper wire; action five: the riveting front and back cylinder 7103 drives the slidable terminal machine fixing plate 7105 to return the terminal riveting press 7101, the riveting die 7102, the terminal guide groove 7108, and the terminal plate 7110.

The first heat shrink tube mechanism 8100, the first core wire exchanging mechanism 9100 and the oven 1100 are commonly used in the market, and the wire taking mechanism 1200 is a commonly used manipulator.

As shown in fig. 10, the aligning mechanism 9300 includes a jack 9310, a jack front-rear cylinder 9320, a jack front-rear cylinder fixing plate 9330, a jack lifting cylinder 9340, and a fixing bracket 9350; action one: the top wire front and back cylinder 9320 drives the top wire 9310 to the top wire core wire position; action two: the top wire piece lifting cylinder 9320 drives the top wire piece 9310 to lift so as to top the folded wire core wire flat; and action III: the front and rear air cylinders 9320 and the lifting air cylinder 9340 of the top wire piece reset in a number-off manner, and drive the top wire piece 9310 to return to the original position.

The whole machine operation flow comprises the following steps: the operator clamps the wire into the clamping groove of the carrier 2015 (and straightens the core wire, stretches the second core wire B as shown by the manual wire-dividing line in FIG. 7, and separates the first core wire A and the third core wire C at two sides to facilitate the wire-dividing mechanism operation; the first branching mechanism 5100 is folded to a required angle, the first core wire stripping mechanism 6100 shortens the first core wire A to a required length and half strips, the first riveting mechanism 7100 rivets the terminal on the second core wire B, the first core wire switching mechanism 8100 cuts the heat-shrinkable sleeve and sleeves the heat-shrinkable sleeve on the second core wire B at a required position and in a heat-shrinkable positioning mode, the first core wire switching mechanism 9100 folds the second core wire B and returns the first core wire A to a straight state, the second core wire stripping mechanism 6200 shortens the first core wire A to a required length and half strips, the second riveting mechanism 7200 rivets the terminal on the first core wire A, the second core wire switching mechanism 8200 cuts the heat-shrinkable sleeve and sleeves the heat-shrinkable sleeve on the first core wire A at a required position and in a semi-peeling mode, the second core wire switching mechanism 9200 folds the first core wire A and sleeves the third core wire C in a straight state, the third core wire stripping mechanism 6300 shortens the third core wire C to a required length and half strips, the third riveting mechanism 7300 rivets the terminal on the third core wire A back to a straight state, the third core wire C is bent at a required position and full-shrinkable sleeve on the third core wire C1100 is required to be positioned at a required position, the oven 1100 is cut and full-open-ended, the carrier 2015 is lowered by the carrier lifting mechanism 3000 at the tail end; the carrier reflow mechanism 4000 reflows the carrier 2015 to the front of the apparatus; the carrier lifting mechanism 3000 in the front stage lifts the carrier 2015 up to wait for the wire.

The foregoing description is only of the preferred embodiments of the present invention, and is not intended to limit the scope of the invention, but rather is intended to cover any equivalents of the structures or equivalent processes disclosed herein or in the alternative, which may be employed directly or indirectly in other related arts.

Claims

1. The 2-core or 3-core wire rod penetrating and drying heat-shrinking sleeve equipment is characterized by comprising a mounting plate and a plurality of groups of linearly connected slideway carrying mechanisms arranged on the mounting plate, wherein each slideway carrying mechanism comprises two parallel slideway rails, a poking cylinder, a plurality of carrier sliding blocks, a linear sliding rail and a pushing plate, the bottoms of the two slideway rails are respectively provided with a support column group, the carrier sliding blocks are slidably arranged on the slideway rails, each carrier sliding block is provided with a carrier, the poking cylinder is parallel to the slideway rails and is arranged on the support column groups, the linear sliding rail is slidably arranged on the support column groups, the pushing plate is arranged at one end of the linear sliding rail, and the output end of the poking cylinder is connected with the pushing plate; an elastic toggle block is arranged at the position, corresponding to each carrier sliding block, on the linear sliding rail; carrier lifting mechanisms are respectively arranged at two ends of the mounting plate, which correspond to the slideway carrying mechanisms, carrier reflux mechanisms are arranged below the mounting plate, and two ends of the carrier reflux mechanisms correspond to the two carrier lifting mechanisms respectively; the first core wire stripping mechanism, the second core wire stripping mechanism and the third core wire stripping mechanism are consistent in structure, the first riveting mechanism, the second riveting mechanism and the third riveting mechanism are consistent in structure, the first heat-shrinkable sleeve mechanism, the second heat-shrinkable sleeve mechanism and the third heat-shrinkable sleeve mechanism are consistent in structure, and the first core wire stripping mechanism and the second core wire stripping mechanism are consistent in structure; the first branching mechanism comprises a branching block, a branching block fixing plate, a front cylinder fixing plate, a rear cylinder fixing plate, a front cylinder, a rear cylinder, a fixing bottom plate, a sliding plate, a branching sliding rail, a branching lifting cylinder and a branching cylinder fixing plate; the fixed bottom plate is arranged on the mounting plate, the branching sliding rail is arranged on the fixed bottom plate along the direction perpendicular to the sliding groove track, the branching cylinder fixing plate is arranged on the branching sliding rail in a sliding way, the branching lifting cylinder is arranged on the branching cylinder fixing plate, the branching block fixing plate is arranged at the output end of the branching lifting cylinder, the branching block is arranged on the branching block fixing plate, the front and rear cylinders are arranged on one side of the fixed bottom plate through the front and rear cylinder fixing plate, and the driving direction of the front and rear cylinders is parallel to the branching sliding rail;

the first core wire stripping mechanism comprises an opening and closing cylinder, an upper cutter rest rack, a waste suction pipe, a transmission gear, a vertical support plate, a lower cutter rest rack, an upper stripping cutter set, a vertical linear guide rail, a lower stripping cutter set, a lower cutter rest, a first core wire stripping front-back cylinder, a second core wire stripping front-back cylinder, a first core wire stripping fixed plate, a first core wire stripping bottom plate, a second core wire stripping fixed plate, a front-back sliding plate and a front-back linear guide rail;

the first riveting mechanism comprises a terminal riveting machine, a riveting die, a riveting front cylinder and a riveting rear cylinder, a riveting front cylinder fixing plate and a riveting rear cylinder fixing plate, a slidable terminal machine fixing plate, a riveting forward limiting block, a riveting bottom plate, a terminal guide groove, a riveting linear guide rail and a terminal disc.

2. The 2-core or 3-core wire rod through-drying heat-shrinking sleeve device according to claim 1, wherein the mounting plate is provided with a cylinder mounting frame, and the cylinder mounting frame is provided with a wire pressing cylinder at positions corresponding to the first wire separating mechanism, the first core wire stripping mechanism, the first set of heat-shrinking sleeve mechanism, the first core wire replacing mechanism, the second core wire stripping mechanism, the second set of heat-shrinking sleeve, the second core wire replacing mechanism, the third core wire stripping mechanism, the third set of heat-shrinking sleeve machine and the straightening mechanism.

3. The 2-core or 3-core wire rod penetrating and baking heat-shrinking sleeve device according to claim 2, wherein the cylinder mounting frame is provided with rail lifting cylinders at positions corresponding to the first riveting mechanism, the second riveting mechanism and the third riveting mechanism, lifting rails and guide post groups for lifting the lifting rails are arranged below the rail lifting cylinders, and the rail lifting cylinders are in driving connection with the guide post groups.

4. The 2-core or 3-core wire rod through-baking heat shrink sleeve device according to claim 2, wherein each of the carrier lifting mechanisms comprises a support plate, an upper limit plate, a lifting linear guide rail, a chute fixing plate, a lifting chute, a chute lifting cylinder and a lower limit plate, the support plate is vertically arranged on the mounting plate in a penetrating manner, the lifting linear guide rail is arranged on the support plate in a vertical direction, the upper limit plate and the lower limit plate are arranged at two ends of the lifting linear guide rail, the chute fixing plate is slidably arranged on the lifting linear guide rail, the lifting chute is arranged on the chute fixing plate, and one end of the chute fixing plate is connected with the chute lifting cylinder.

5. The 2-core or 3-core wire rod penetrating and drying heat-shrinking sleeve device according to claim 2, wherein the carrier backflow mechanism comprises a backflow belt, a belt fixing frame and two carrier driving components, the backflow belt is arranged at the bottom of the mounting plate in parallel through the belt fixing frame, two ends of the backflow belt correspond to the two carrier lifting mechanisms respectively, and the two carrier driving components are arranged at the side edges of two ends of the backflow belt; each carrier driving assembly comprises a transverse moving air cylinder, a telescopic air cylinder and a carrier pulling rod, wherein the telescopic air cylinder is arranged at the driving end of the transverse moving air cylinder, and the carrier pulling rod is arranged at the driving end of the telescopic air cylinder.

6. The 2-core or 3-core wire rod through-drying heat-shrinking sleeve device according to claim 1, wherein the first branching mechanism comprises a branching block, a branching block fixing plate, a front and rear cylinder, a fixing bottom plate, a sliding plate, a branching sliding rail, a branching lifting cylinder and a branching cylinder fixing plate; the fixed baseplate is arranged on the mounting plate, the branching sliding rail is arranged on the fixed baseplate along the direction perpendicular to the sliding groove track, the branching cylinder fixing plate is arranged on the branching sliding rail in a sliding way, the branching lifting cylinder is arranged on the branching cylinder fixing plate, the branching block fixing plate is arranged at the output end of the branching lifting cylinder, the branching block is arranged on the branching block fixing plate, the front and rear cylinders are arranged on one side of the fixed baseplate through the front and rear cylinder fixing plates, and the driving direction of the front and rear cylinders is parallel to the branching sliding rail.