CN115230189B - Hard disk data line production sleeve pipe equipment - Google Patents

Abstract

The invention discloses a hard disk data line production sleeve pipe device, which relates to the technical field of data line production and comprises a base, a conveyor belt arranged at the upper right end of the base and a plurality of fixing mechanisms arranged on the conveyor belt and used for clamping data lines, wherein the fixing mechanisms are uniformly arranged on the conveyor belt, the upper left end of the base is provided with a support, a sleeve pipe mechanism used for sleeving a heat shrinkable pipe outside the data lines is arranged on the support in a left-right sliding mode, the sleeve pipe mechanism is driven by a moving mechanism to move left and right, and one end, far away from the data lines, of the sleeve pipe mechanism is provided with a cutting mechanism used for cutting the heat shrinkable pipe. According to the invention, the upper end and the lower end of the flattened heat-shrinkable tube are clamped by the clamping component to fix the upper end and the lower end of the heat-shrinkable tube, and then the middle part of the heat-shrinkable tube is extruded by the clamping component, so that the flattened heat-shrinkable tube is rounded, the heat-shrinkable tube is conveniently sleeved outside the data line, and the efficiency of the data line sleeve is improved.

Description

Hard disk data line production sleeve pipe equipment

Technical Field

The invention relates to the technical field of data line production, in particular to a hard disk data line production casing pipe device.

Background

The hard disk is one of the main storage media of the computer; the data line is used for connecting the mobile equipment and the computer to achieve the purpose of data transmission or communication. A heat-shrinkable sleeve is sleeved on the surface in the production process of the data line;

the heat shrinkable sleeve is a novel environment-friendly halogen-free flame retardant sleeve (made of polyolefin material), the outer layer is formed by compounding and processing a high-quality soft cross-linked polyolefin material and an inner layer of hot melt adhesive, can provide insulation protection for wires, cables, wire terminals and data lines, has the advantages of excellent flame retardance, environmental protection, insulation performance, high softness, elasticity, low shrinkage temperature, high shrinkage speed and the like, is particularly suitable for protecting temperature-sensitive parts, can be widely applied to coating and insulation protection of wire processing, welding spot protection, coating of electronic components, insulation protection of resistance and capacitance, rust prevention and corrosion prevention treatment of metal products, marking or color marking of wires and the like; current data line bushing processing is most with certain length of pyrocondensation pipe shearing earlier, overlaps the pyrocondensation pipe cover outside the data line again, but because the phenomenon that flattens can appear in the pyrocondensation pipe when cuting, thereby lead to overlapping the pyrocondensation pipe cover when the data line is outside, need carry out the whole circle to the pyrocondensation pipe earlier, thereby lead to the sheathed tube efficiency of data line lower.

Disclosure of Invention

The invention aims to solve the problems of the prior art, and provides a hard disk data line production casing device.

In order to achieve the purpose, the invention adopts the following technical scheme:

a hard disk data line production sleeve pipe device comprises a base, a plurality of conveying belts arranged at the upper right end of the base and a plurality of fixing mechanisms arranged on the conveying belts and used for clamping data lines, wherein the fixing mechanisms are uniformly arranged on the conveying belts;

the sleeve mechanism comprises a base plate which is arranged on a support in a left-right sliding mode, a through hole for a heat shrinkable tube and a data line to penetrate through is formed in the middle of the base plate, a positioning ring is embedded in the inner wall of the through hole, clamping assemblies for clamping the upper end and the lower end of the heat shrinkable tube are symmetrically arranged at the upper end and the lower end of the through hole, sliding plates are arranged at the ends, deviating from each other, of the two clamping assemblies, the ends, deviating from each other, of the two sliding plates penetrate through the inner wall of the positioning ring in a vertical sliding mode, one end, far away from the clamping assemblies, of any one positioning ring is installed with the movable end of the first electric telescopic rod, and the fixed end of the first electric telescopic rod is fixedly connected with the inner wall of the base plate; one side of each of the two sliding plates is meshed and connected with a first gear, the two first gears are rotationally connected with the inner wall of the base plate, tooth grooves meshed with the two first gears are formed in the surfaces of the two sliding plates respectively, the two first gears are arranged in a left-right staggered mode, the two first gears are meshed and connected with an inner gear, and the inner gear is rotationally connected with the inner wall of the base plate;

the clamping assembly comprises a U-shaped frame arranged at the end part of a sliding plate, L-shaped clamping plates are arranged at the front end and the rear end of the inner wall of the U-shaped frame in a rotating mode through first torsion spring shafts, first wire rollers are fixedly arranged at the ends, far away from the two L-shaped clamping plates, of the two first torsion spring shafts, connecting wires are wound on the surfaces of the first wire rollers, one movable end of each connecting wire is fixed on the surface of each first wire roller, guide wheels are arranged at the front end and the rear end of the outer wall of the U-shaped frame, the other movable end of each connecting wire penetrates through the guide wheels and is fixed on the surface of each second wire roller, a mounting shaft of each second wire roller is fixed at the end part of a sliding frame, the sliding frame is arranged on the surface of a fixed cover, one end, far away from the second wire roller, of the fixed cover is fixedly connected with the inner wall of a positioning ring, the two sliding plates respectively penetrate through the insides of the two fixed covers in a sliding mode, and a first reset spring is arranged between the sliding frame and the inner wall of the fixed cover;

pull plates are symmetrically arranged at the front end and the rear end of the through hole, one ends, close to each other, of the two pull plates are rotatably connected with contact heads through second torsion spring shafts, the two contact heads are respectively contacted with the inner walls of the front end and the rear end of the heat shrink tube, the ends, away from each other, of the two pull plates slide back and forth to penetrate through the inner wall of the positioning ring, one sides of the two pull plates are respectively meshed with a second gear, the two second gears are respectively rotatably connected with the inner wall of the substrate, tooth blocks meshed with the two second gears are respectively arranged on the surfaces of the two pull plates, one ends, far away from the tooth blocks, of the two second gears are respectively meshed with a third gear, the two third gears are rotatably connected with the inner wall of the substrate, the two third gears are respectively meshed with the inner gear, and the two third gears are arranged in a vertically staggered manner;

and one end of the contact head, which is far away from the pulling plate, is triangular.

As a further description of the above technical solution:

the moving mechanism comprises a threaded seat arranged at the top end of the substrate and a lead screw matched with the threaded seat, the lead screw is rotationally arranged in the positioning seat, the lead screw is driven by a motor, a through groove used for the threaded seat to slide left and right is formed in the bottom end of the threaded seat, and the left end of the positioning seat is fixedly connected with the support through a vertical plate.

As a further description of the above technical solution:

the cutting mechanism comprises a mounting plate and scissors, the mounting plate is arranged at the top end of the support in a left-right mode, the scissors are used for cutting a heat shrink tube, a through hole is formed in the middle of the mounting plate, a rotating shaft at the rotating position of the scissors is fixedly connected with the inner wall of the through hole, the tops of two blades in the scissors are respectively abutted to two extrusion plates, the two extrusion plates are located at the limit positions of the two blades when the scissors are not closed, one ends, away from the blades, of the two extrusion plates are arranged in the fixing seat in a front-back sliding mode, one ends, away from the blades, of the two extrusion plates are respectively connected with the bottom ends of a first toothed plate and a second toothed plate, the first toothed plate and the second toothed plate are arranged in a staggered mode, a fourth gear is meshed and connected between the ends, close to the first toothed plate and the second toothed plate, one end, away from the fourth gear, of the first toothed plate is connected with the movable end of a second electric telescopic rod, the second electric telescopic rod is arranged in the fixing seat, a slide way for the two extrusion plates to slide back is formed in the bottom of the fixing seat, extension plates are arranged at the front-back two ends of the fixing seat, and extension plates are respectively, and second reset springs are fixedly arranged in the interior of the fixing seat;

the left upper and lower both ends of mounting panel are all fixed and are provided with T form slide bar, two the T form slide bar slides with the inner wall of two guide holders respectively and pegs graft, the guide holder is fixed to be inlayed in locating the riser, and is provided with third reset spring, two between the inner wall of T form slide bar and guide holder T form slide bar and the crisscross setting of scissors.

As a further description of the above technical solution:

the inner wall on fixing base top has from left to right set gradually first pressure sensor, second pressure sensor and third pressure sensor, first pressure sensor and screw thread seat fixed mounting, the equal fixed mounting in top of second pressure sensor and third pressure sensor has the slide, the screw thread seat top is offered and is used for the gliding spout of slide, the top of screw thread seat is provided with the locating plate, the slide passes through fixing bolt and is fixed with the locating plate, set up in slide and the locating plate with fixing bolt complex screw hole, screw hole in the locating plate is a plurality of, first pressure sensor, second pressure sensor and third pressure sensor all are connected with control panel electricity.

As a further description of the above technical solution:

the sliding covers are arranged at the ends, close to the threaded seat, of the first pressure sensor, the second pressure sensor and the third pressure sensor, and are provided with sliding covers, and the inner walls of the sliding covers are provided with fourth reset springs respectively between the first pressure sensor, the second pressure sensor and the third pressure sensor.

As a further description of the above technical solution:

the fixing mechanism comprises a T-shaped lower seat arranged on the conveying belt and an upper seat rotatably arranged on the T-shaped lower seat through a hinge, wherein placing grooves for placing data lines are formed in one ends, close to the upper seat, of the T-shaped lower seat, lug plates are arranged at one ends, far away from the hinge, of the T-shaped lower seat and one ends, far away from the hinge, of the upper seat, of the T-shaped lower seat, the lug plates are symmetrically arranged up and down, and the two lug plates are fixed through locking bolts;

the lower part of the T-shaped lower seat is provided with a bearing plate in a left-right sliding mode, and a fifth reset spring is arranged between the bearing plate and the inner wall of the T-shaped lower seat.

As a further description of the above technical solution:

the left lower extreme of T form lower seat inlays and is equipped with infrared emitter, the right-hand member of base plate inlays and is equipped with the infrared receiver with infrared emitter complex, infrared receiver is connected with control panel electricity.

As a further description of the above technical solution:

control panel installs in the support, install treater and relay in the control panel, first pressure sensor, second pressure sensor, third pressure sensor and infrared receiver's output all is connected with the input electricity of treater, the output of treater is connected with the input electricity of relay, the output of relay is connected with motor, first electric telescopic handle and second electric telescopic handle electricity respectively.

As a further description of the above technical solution:

the vertical plate is internally provided with a line passing hole for the heat shrinkable tube to pass through, the front inner wall and the rear inner wall of the line passing hole are fixedly provided with guide pieces which are abutted against the front end and the rear end of the heat shrinkable tube, the guide pieces extend out of the right end of the line passing hole, and a gap is reserved between the right end of each guide piece and the shearing end of the heat shrinkable tube.

As a further description of the above technical solution:

the flattening assembly comprises two side plates arranged at the left end of the vertical plate, the two side plates are positioned at the upper end and the lower end of the wire passing hole, two groups of pressing roller sets are arranged between the adjacent ends of the side plates from left to right, the pressing roller sets are specifically two rotating rollers, and the two rotating rollers are arranged in the front and the back.

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

according to the invention, the upper end and the lower end of the flattened heat-shrinkable tube are clamped by the clamping component to fix the upper end and the lower end of the heat-shrinkable tube, and then the middle part of the heat-shrinkable tube is extruded by the clamping component, so that the flattened heat-shrinkable tube is rounded, the heat-shrinkable tube is conveniently sleeved outside a data line, and the efficiency of a data line sleeve is improved;

the front end and the rear end of the flattened heat-shrinkable tube are used for driving the two contact heads to deviate from each other through the two pulling plates, so that the middle part of the heat-shrinkable tube is bent towards the same side when the U-shaped frame extrudes the middle part of the heat-shrinkable tube, and the middle part of the flattened heat-shrinkable tube is guaranteed to be rounded.

Drawings

FIG. 1 is a schematic diagram of an overall structure of a hard disk data line casing production device according to the present invention;

FIG. 2 is a state diagram of the motion of FIG. 1;

FIG. 3 is a front view of a sleeve mechanism in the sleeve device for producing a hard disk data line according to the present invention;

FIG. 4 is a side view of a sleeve mechanism in the sleeve device for producing the hard disk data line according to the present invention;

FIG. 5 is a schematic structural diagram of the engagement between the second gear and the third gear in the hard disk data line casing production equipment according to the present invention;

FIG. 6 is a schematic structural diagram of the meshing between the first gear and the internal gear in the hard disk data line casing production equipment according to the present invention;

FIG. 7 is a schematic view of an internal structure of a fixing cover in a hard disk data line casing production apparatus according to the present invention;

FIG. 8 is a state diagram of the motion of FIG. 7;

FIG. 9 is a schematic structural diagram of a clamping assembly in the hard disk data line casing production equipment according to the present invention;

FIG. 10 is a side view of the contact head contacting the heat shrinkable tube in the hard disk data line casing production equipment according to the present invention;

fig. 11 is a front view of the contact head contacting with the heat shrinkable tube in the hard disk data line casing production apparatus according to the present invention;

FIG. 12 is a schematic structural diagram of a hard disk data line casing production apparatus according to the present invention, in which the contact is flush with the pull plate;

FIG. 13 is a schematic structural diagram of a moving mechanism in a casing manufacturing apparatus for a hard disk data line according to the present invention;

FIG. 14 is a schematic structural diagram of a sliding seat in a hard disk data line casing production apparatus according to the present invention;

FIG. 15 is a side view of a cutting mechanism of the hard disk data line production casing apparatus according to the present invention;

FIG. 16 is a schematic structural diagram of a fixing mechanism in a hard disk data line casing production apparatus according to the present invention;

fig. 17 is a state diagram of the motion of fig. 16.

In the figure: 1. a base; 2. a conveyor belt; 3. a data line; 4. a fixing mechanism; 41. a T-shaped lower seat; 42. an upper seat; 43. a support plate; 5. heat shrink tubing; 6. a bushing mechanism; 61. a substrate; 62. a positioning ring; 63. a clamping assembly; 631. a U-shaped frame; 632. an L-shaped splint; 633. a first wire roll; 634. a guide wheel; 635. a connecting wire; 636. a second wire roller; 637. a carriage; 638. a fixed cover; 64. a slide plate; 65. a first gear; 66. an internal gear; 67. a first electric telescopic rod; 68. pulling a plate; 681. a contact head; 69. a second gear; 610. a third gear; 7. a moving mechanism; 71. a threaded seat; 72. a screw rod; 73. positioning seats; 74. a first pressure sensor; 75. a second pressure sensor; 76. a third pressure sensor; 77. a slide base; 78. positioning a plate; 79. a slide cover; 8. a cutting mechanism; 81. scissors; 811. a pressing plate; 812. a fixed seat; 813. a first toothed plate; 814. a second toothed plate; 815. a fourth gear; 816. a second electric telescopic rod; 817. an extension plate; 82. mounting a plate; 83. a T-shaped slide bar; 84. a guide seat; 85. a guide piece; 9. flattening the assembly; 91. a side plate; 92. rotating the roller; 10. a support; 101. a vertical plate.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments.

In the description of the present invention, it is to be understood that the terms "upper", "lower", "front", "rear", "left", "right", "top", "bottom", "inner", "outer", and the like, indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings, are merely for convenience in describing the present invention and simplifying the description, and do not indicate or imply that the device or element being referred to must have a particular orientation, be constructed and operated in a particular orientation, and thus, should not be construed as limiting the present invention.

Referring to fig. 1-17, a hard disk data line production sleeve pipe device comprises a base 1, a conveyor belt 2 arranged at the upper right end of the base 1 and a plurality of fixing mechanisms 4 arranged on the conveyor belt 2 and used for clamping a data line 3, wherein the fixing mechanisms 4 are uniformly arranged on the conveyor belt 2, a support 10 is arranged at the upper left end of the base 1, a sleeve pipe mechanism 6 used for sleeving a heat shrinkable pipe 5 outside the data line 3 is arranged on the support 10 in a left-right sliding manner, the sleeve pipe mechanism 6 is driven by a moving mechanism 7 to move left and right, a cutting mechanism 8 used for cutting the heat shrinkable pipe 5 is arranged at one end of the sleeve pipe mechanism 6 far away from the data line 3, and a flattening component 9 used for flattening the heat shrinkable pipe 5 is arranged at one end of the cutting mechanism 8 far away from the sleeve pipe mechanism 6;

the sleeve mechanism 6 comprises a base plate 61 arranged on the support 10 in a left-right sliding manner, a through hole for the heat shrinkable tube 5 and the data wire 3 to pass through is formed in the middle of the base plate 61, a positioning ring 62 is embedded in the inner wall of the through hole, clamping assemblies 63 for clamping the upper end and the lower end of the heat shrinkable tube 5 are symmetrically arranged at the upper end and the lower end of the through hole, sliding plates 64 are arranged at the ends of the two clamping assemblies 63, which are deviated from each other, the ends of the two sliding plates 64, which are deviated from each other, penetrate through the inner wall of the positioning ring 62 in a vertical sliding manner, one end of any positioning ring 62, which is far away from the clamping assembly 63, is installed at the movable end of the first electric telescopic rod 67, and the fixed end of the first electric telescopic rod 67 is fixedly connected with the inner wall of the base plate 61; one side of each of the two sliding plates 64 is engaged with a first gear 65, the two first gears 65 are rotationally connected with the inner wall of the base plate 61, tooth grooves engaged with the two first gears 65 are respectively formed in the surfaces of the two sliding plates 64, the two first gears 65 are arranged in a left-right staggered manner, the two first gears 65 are engaged with an inner gear 66, and the inner gear 66 is rotationally connected with the inner wall of the base plate 61;

the clamping assembly 63 comprises a U-shaped frame 631 mounted at the end of a sliding plate 64, wherein L-shaped clamping plates 632 are rotatably arranged at the front end and the rear end of the inner wall of the U-shaped frame 631 through first torsion spring shafts, first wire rollers 633 are fixedly mounted at the ends of the two first torsion spring shafts far away from the two L-shaped clamping plates 632, connecting wires 635 are wound on the surfaces of the first wire rollers 633, one movable ends of the connecting wires 635 are fixed on the surfaces of the first wire rollers 633, guide wheels 634 are arranged at the front end and the rear end of the outer wall of the U-shaped frame 631, the other movable ends of the connecting wires 635 penetrate through the guide wheels 634 and are fixed on the surfaces of second wire rollers 636, mounting shafts of the second wire rollers 636 are fixed at the ends of carriages 637, the carriages 637 are arranged on the surfaces of fixed covers 638, one ends of the fixed covers 638 far away from the second wire rollers 636 are fixedly connected with the inner wall of a positioning ring 62, the two sliding plates 64 respectively penetrate through the insides of the two fixed covers 638, and a first return spring is arranged between the carriages 637 and the inner wall of the fixed covers 638; specifically, the first electric telescopic rod 67 is controlled to extend to drive one of the sliding plates 64 to approach the middle of the through hole, at this time, the sliding slot on one side of the sliding plate 64 drives the first gear 65 to rotate, and further drives the internal gear 66 to rotate, and further drives the other first gear 65 to rotate, and further drives the other sliding plate 64 to synchronously approach the middle of the through hole, at this time, the two sliding plates 64 respectively penetrate through the inside of the two fixed covers 638, and further the two sliding plates 64 respectively drive the two U-shaped frames 631 to approach each other; in the process that the two U-shaped frames 631 approach each other, the two first wire rollers 633 in the U-shaped frames 631 rotate under the action of the two second wire rollers 636 and the first return spring, so as to drive the first torsion spring shaft to rotate, and further to enable the two L-shaped clamp plates 632 to approach each other to clamp the heat shrinkable tube 5 in the U-shaped frames 631, so as to fix the upper end and the lower end of the heat shrinkable tube 5; at this time, in the process that the two U-shaped frames 631 continuously approach each other, the two U-shaped frames 631 extrude the middle of the heat shrinkable tube 5, so that the flattened heat shrinkable tube 5 is rounded, and the heat shrinkable tube 5 is conveniently sleeved outside the data line 3; in the process that the two U-shaped frames 631 continuously approach each other, at this time, since the two L-shaped clamp plates 632 cannot rotate, the downward movement of the U-shaped frames 631 will drive the sliding plate 64 to slide in the fixed hood 638 to stretch the first return spring;

the front end and the rear end of the through hole are symmetrically provided with pull plates 68, one ends, close to each other, of the two pull plates 68 are rotatably connected with contact heads 681 through second torsion spring shafts, the two contact heads 681 are respectively contacted with the inner walls of the front end and the rear end of the heat shrink tube 5, one ends, away from each other, of the two pull plates 68 are in front-back sliding penetrating through the inner wall of the positioning ring 62, one sides of the two pull plates 68 are respectively in meshing connection with second gears 69, the two second gears 69 are rotatably connected with the inner wall of the base plate 61, tooth blocks meshed with the two second gears 69 are respectively arranged on the surfaces of the two pull plates 68, one ends, far away from the tooth blocks, of the two second gears 69 are respectively in meshing connection with third gears 610, the two third gears 610 are rotatably connected with the inner wall of the base plate 61, the two third gears 610 are respectively in meshing connection with the inner gear 66, and the two third gears 610 are arranged in a vertically staggered manner; specifically, in the process of rotation of the internal gear 66, the two third gears 610 are synchronously driven to synchronously rotate, so that the two second gears 69 are driven to rotate in a meshing manner, and then the two pulling plates 68 are driven to mutually keep away from the middle part of the through hole through the plurality of tooth blocks on the two pulling plates 68, at this time, the two pulling plates 68 drive the front and rear ends of the flattened heat shrinkable tube 5 to be separated, in which the two contact heads 681 are mutually deviated, so that when the U-shaped frame 631 extrudes the middle part of the heat shrinkable tube 5, the middle part of the heat shrinkable tube 5 is prevented from being bent to the same side, and the middle part of the flattened heat shrinkable tube 5 is ensured to be rounded; when the two pulling plates 68 are continuously far away from the middle of the through hole, because the upper end and the lower end of the heat shrinkable tube 5 are clamped at the moment, the two contact heads 681 will extrude the second torsion spring, so that the two contact heads 681 rotate around the second torsion spring shaft, so that the two contact heads 681 are parallel to the two pulling plates 68, the two contact heads 681 can be conveniently separated from the inside of the heat shrinkable tube 5, and the two contact heads 681 can be prevented from driving the heat shrinkable tube 5 to be separated from the data line 3 when the sleeve mechanism 6 moves to the left;

the end of the contact 681 away from the pulling plate 68 is triangular, and specifically, the end of the contact 681 away from the pulling plate 68 is triangular, so that the contact 681 is positioned inside the heat shrinkable tube 5.

Further, the cutting mechanism 8 comprises a mounting plate 82 and scissors 81 for cutting the heat shrinkable tube 5, the mounting plate 82 is arranged at the top end of the support 10 in a left-right mode, a through hole is formed in the middle of the mounting plate 82, a rotating shaft at the rotating position of the scissors 81 is fixedly connected with the inner wall of the through hole, the tops of two blades in the scissors 81 are respectively abutted to two squeezing plates 811, the two squeezing plates 811 are located at the limit positions of the two blades when the scissors 81 are not closed, one ends, far away from the blades, of the two squeezing plates 811 are arranged in the fixing seat 812 in a front-back sliding mode, one ends, far away from the blades, of the two squeezing plates 811 are respectively connected with the bottom ends of the first toothed plate 813 and the second toothed plate 814, the first toothed plate 813 and the second toothed plate 814 are arranged in a staggered mode, a fourth gear 815 is engaged and connected between the close ends of the first toothed plate 813 and the second toothed plate 814, one end, far away from the fourth gear 815 is connected with the movable end of the second electric telescopic rod 816, the fixed end of the second electric telescopic rod 816 is arranged in the fixing seat 812, a slide way for the two squeezing plates 811 to slide is formed at the front-back sliding, extension plates 817, and the inner parts of the fixing seat 812 are respectively arranged on the fixing seat 812, and a return spring 817 is arranged on the fixing seat 812; specifically, the second electric telescopic rod 816 is started to extend, so as to drive the first toothed plate 813 to move backwards, further drive the second toothed plate 814 to move forwards synchronously through the fourth gear 815, further drive the two extrusion plates 811 to approach each other synchronously, further drive the two blades to approach each other, stretch the second return spring until the two blades shear the heat shrink tube 5, and further, the processor sends an instruction to the relay to control the second electric telescopic rod 816 to return;

the upper end and the lower end of the left side of the mounting plate 82 are fixedly provided with T-shaped sliding rods 83, the two T-shaped sliding rods 83 are respectively in sliding insertion connection with the inner walls of the two guide seats 84, the guide seats 84 are fixedly embedded in the vertical plate 101, a third reset spring is arranged between the T-shaped sliding rods 83 and the inner walls of the guide seats 84, the two T-shaped sliding rods 83 and the scissors 81 are arranged in a staggered mode, specifically, when the base plate 61 moves rightwards, the third reset spring drives the T-shaped sliding rods 83 to slide out of the guide seats 84, so that the mounting plate 82 moves rightwards until the shearing end of the scissors 81 in the mounting plate 82 is located at the position when the U-shaped frame 631 does not move rightwards; when the substrate 61 moves leftwards and returns, the substrate 61 is in contact with the mounting plate 82, so that the mounting plate 82 is driven to move leftwards, the second return spring is extruded, and the scissors 81 are far away from the cutting end of the heat shrink tube 5; further, the treater sends the instruction for the relay, and control conveyer belt 2 starts for 3 data lines that sheathe in 5 pyrocondensation pipes keep away from sleeve pipe mechanism 6, and the next data line 3 of being convenient for is close to sleeve pipe mechanism 6, thereby is convenient for the continuous sleeve pipe work of a plurality of data lines 3.

Further, a first pressure sensor 74, a second pressure sensor 75 and a third pressure sensor 76 are sequentially arranged on the inner wall of the top end of the fixed seat 812 from left to right, the first pressure sensor 74 is fixedly mounted with the threaded seat 71, slide seats 77 are fixedly mounted on the top ends of the second pressure sensor 75 and the third pressure sensor 76, a sliding groove for sliding the slide seats 77 is formed in the top of the threaded seat 71, a positioning plate 78 is arranged on the top end of the threaded seat 71, the slide seats 77 are fixed with the positioning plate 78 through fixing bolts, threaded holes matched with the fixing bolts are formed in the slide seats 77 and the positioning plate 78, the number of the threaded holes in the positioning plate 78 is multiple, the first pressure sensor 74, the second pressure sensor 75 and the third pressure sensor 76 are electrically connected with a control panel, specifically, the distance of the heat shrinkable tube 5 sleeved on the data line 3 is determined, the length of the heat shrinkable tube 5 is determined, the distance between the second pressure sensor 75 and the first pressure sensor 74 is determined according to the length, the slide seats 77 on the second pressure sensor 75 are fixed on the positioning plate 78 through the fixing bolts, and the positioning of the second pressure sensor 75 is positioned; further, the moving position of the sleeve mechanism 6 is determined according to the determined distance of the heat shrinkable tube 5 sleeved on the data line 3, the position of the third pressure sensor 76 is determined according to the moving position, and further, the sliding seat 77 of the third pressure sensor 76 is fixed on the positioning plate 78 through the fixing bolt, so that the positioning of the third pressure sensor 76 is realized.

Further, the sliding covers 79 are respectively arranged at the ends, close to the threaded seat 71, of the first pressure sensor 74, the second pressure sensor 75 and the third pressure sensor 76 in a sliding cover mode, and fourth return springs are respectively arranged between the inner walls of the three sliding covers 79 and the first pressure sensor 74, the second pressure sensor 75 and the third pressure sensor 76.

Further, the fixing mechanism 4 comprises a T-shaped lower seat 41 arranged on the conveyor belt 2 and an upper seat 42 rotatably arranged on the T-shaped lower seat 41 through a hinge, placing grooves for placing the data lines 3 are formed in one ends, close to the T-shaped lower seat 41 and the upper seat 42, of the T-shaped lower seat 41 and one ends, far away from the hinge, of the upper seat 42, lug plates are arranged on the ends, far away from the hinge, of the T-shaped lower seat 41 and the upper seat 42, the two lug plates are arranged in an up-and-down symmetrical mode, and the two lug plates are fixed through locking bolts; specifically, a plurality of data wires 3 are sequentially placed on the placing grooves of a plurality of T-shaped lower seats 41, then the upper seat 42 is sequentially rotated, and then the two ear plates are fixed together by the locking bolt, so that the T-shaped lower seats 41 and the upper seat 42 are fixed, and the data wires 3 are fixed between the T-shaped lower seats 41 and the upper seat 42; meanwhile, when the data line 3 is fixed, the end part of the data line 3 is erected on the supporting plate 43, so that the data line 3 is in a straight state, and the heat shrinkable tube 5 is conveniently sleeved outside the data line 3 when moving to the right at the later stage;

the lower part of the T-shaped lower seat 41 is provided with the supporting plate 43 in a left-right sliding manner, a fifth return spring is arranged between the supporting plate 43 and the inner wall of the T-shaped lower seat 41, specifically, through the arrangement of the supporting plate 43, the end part of the data line 3 is prevented from collapsing, and when the substrate 61 moves to the right, the substrate 61 drives the supporting plate 43 to move to the right to extrude the fifth return spring, so that the heat-shrinkable tube 5 is conveniently sleeved outside the data line 3, and when the substrate 61 moves to the left to be reset, the fifth return spring drives the supporting plate 43 to reset to bear the data line 3 again;

further, an infrared emitter is embedded at the lower left end of the T-shaped lower seat 41, an infrared receiver matched with the infrared emitter is embedded at the right end of the substrate 61, and the infrared receiver is electrically connected with the control panel.

Further, control panel installs in support 10, installs treater and relay in the control panel, and first pressure sensor 74, second pressure sensor 75, third pressure sensor 76 and infrared receiver's output all is connected with the input electricity of treater, and the output of treater is connected with the input electricity of relay, and the output of relay is connected with motor, first electric telescopic handle 67 and second electric telescopic handle 816 electricity respectively.

Further, it is used for the line hole of crossing that pyrocondensation pipe 5 passed to have seted up in riser 101, cross the equal fixed mounting of the front and back inner wall in line hole have with the pyrocondensation pipe 5 front and back end butt guide strip 85, guide strip 85 stretches out the right-hand member in line hole, and leave the clearance between the right-hand member of guide strip 85 and the end of cuting of pyrocondensation pipe 5, and is concrete, setting through guide strip 85, realize the direction of pyrocondensation pipe 5, restrict the current situation of pyrocondensation pipe 5, the port of pyrocondensation pipe 5 opens after avoiding pyrocondensation pipe 5 to pass the line hole.

Further, it includes two curb plates 91 that set up in riser 101 left end to flatten subassembly 9, two curb plates 91 are located the upper and lower both ends of crossing the line hole, from left to right be provided with two sets of compression roller sets between the one end that two curb plates 91 are close, the compression roller set specifically is two pivoted and changes roller 92, and two change roller 92 set up from front to back, it is specific, pass the tip of pyrocondensation pipe 5 between two change rollers 92 in two sets of compression roller sets earlier, make the tip of pyrocondensation pipe 5 flatten, pass the line hole of crossing in riser 101 after that, and make the tip of pyrocondensation pipe 5 be located between two front and back guide vanes 85, realize the location of pyrocondensation pipe 5 tip, flatten the location through pyrocondensation pipe 5 tip, be convenient for L form splint 632 presss from both sides tight pyrocondensation pipe 5, be convenient for scissors 81 cuts pyrocondensation pipe 5 simultaneously.

The working principle is as follows: when the device is used, the distance between the heat shrinkable tube 5 and the data line 3 is firstly determined, the length of the heat shrinkable tube 5 is determined, the distance between the second pressure sensor 75 and the first pressure sensor 74 is determined according to the length, and further, the sliding seat 77 on the second pressure sensor 75 is fixed on the positioning plate 78 through the fixing bolt, so that the second pressure sensor 75 is positioned; further, the moving position of the sleeve mechanism 6 is determined according to the determined distance of the heat shrinkable tube 5 sleeved on the data line 3, the position of the third pressure sensor 76 is determined according to the moving position, and further, the sliding seat 77 of the third pressure sensor 76 is fixed on the positioning plate 78 through a fixing bolt, so that the positioning of the third pressure sensor 76 is realized;

further, the end of the heat shrinkable tube 5 is firstly passed through between two rotating rollers 92 in two sets of pressure roller sets, so that the end of the heat shrinkable tube 5 is flattened, and then passed through the wire passing hole in the vertical plate 101, and the end of the heat shrinkable tube 5 is positioned between the front and rear two guide pieces 85, so that the end of the heat shrinkable tube 5 is positioned, and finally the end of the heat shrinkable tube 5 is positioned between the upper and lower two U-shaped frames 631; simultaneously, two contact heads 681 are respectively contacted with the inner walls of the front and rear ends of the heat shrinkable tube 5;

further, the first electric telescopic rod 67 is started to extend to drive one of the sliding plates 64 to approach the middle of the through hole, at this time, the sliding groove on one side of the sliding plate 64 drives the first gear 65 to rotate, further drives the internal gear 66 to rotate, further drives the other first gear 65 to rotate, further drives the other sliding plate 64 to synchronously approach the middle of the through hole, at this time, the two sliding plates 64 respectively penetrate through the inside of the two fixed covers 638, and further the two sliding plates 64 respectively drive the two U-shaped frames 631 to approach each other;

in the process that the two U-shaped frames 631 approach each other, the two first wire rollers 633 in the U-shaped frames 631 rotate under the action of the two second wire rollers 636 and the first return spring, so as to drive the first torsion spring shaft to rotate, and further to enable the two L-shaped clamp plates 632 to approach each other to clamp the heat shrinkable tube 5 in the U-shaped frames 631, so as to fix the upper end and the lower end of the heat shrinkable tube 5; at this time, in the process that the two U-shaped frames 631 continuously approach each other, the two U-shaped frames 631 extrude the middle of the heat shrinkable tube 5, so that the flattened heat shrinkable tube 5 is rounded, and the heat shrinkable tube 5 is conveniently sleeved outside the data line 3; in the process that the two U-shaped frames 631 continuously approach each other, at this time, since the two L-shaped clamp plates 632 cannot rotate, the downward movement of the U-shaped frames 631 will drive the sliding plate 64 to slide in the fixed cover 638 to stretch the first return spring;

during the rotation of the internal gear 66, the two third gears 610 are synchronously driven to synchronously rotate, so that the two second gears 69 are driven to rotate in a meshing manner, and then the two pulling plates 68 are driven to mutually keep away from the middle part of the through hole through the plurality of tooth blocks on the two pulling plates 68, at the moment, the two pulling plates 68 drive the front end and the rear end of the flattened heat-shrinkable tube 5, which are separated from each other, of the two contact heads 681, so that when the U-shaped frame 631 extrudes the middle part of the heat-shrinkable tube 5, the middle part of the heat-shrinkable tube 5 is prevented from being bent to the same side, and the middle part of the flattened heat-shrinkable tube 5 is ensured to be round;

when the two pulling plates 68 are continuously far away from the middle of the through hole, because the upper end and the lower end of the heat shrinkable tube 5 are clamped at the moment, the two contact heads 681 will extrude the second torsion spring, so that the two contact heads 681 rotate around the second torsion spring shaft, so that the two contact heads 681 are parallel to the two pulling plates 68, the two contact heads 681 can be conveniently separated from the inside of the heat shrinkable tube 5, and the two contact heads 681 can be prevented from driving the heat shrinkable tube 5 to be separated from the data line 3 when the sleeve mechanism 6 moves to the left;

further, a plurality of data wires 3 are sequentially placed on the placing grooves of the plurality of T-shaped lower seats 41, then the upper seat 42 is sequentially rotated, and the two ear plates are fixed together through the locking bolt, so that the T-shaped lower seats 41 and the upper seat 42 are fixed, and the data wires 3 are fixed between the T-shaped lower seats 41 and the upper seat 42; meanwhile, when the data line 3 is fixed, the end part of the data line 3 is erected on the supporting plate 43, so that the data line 3 is in a straight state, and the heat shrinkable tube 5 is conveniently sleeved outside the data line 3 when moving to the right at the later stage;

further, the conveyor belt 2 is started to convey the positioned data line 3 to the sleeve mechanism 6, at this time, the infrared emitter on the left side of the T-shaped lower seat 41 is flush with the infrared receiver embedded at the right end of the substrate 61, the infrared receiver receives a signal of the infrared emitter and sends the signal to the processor, the processor sends an instruction to the relay, the conveyor belt 2 is controlled to stop, the motor is controlled to rotate forwards, the lead screw 72 is driven to rotate, the threaded seat 71 is driven to move rightwards, the substrate 61 is driven to move rightwards, and the clamped heat shrink tube 5 is made to be close to the data line 3; when the base plate 61 moves to the right, the third reset bomb drives the T-shaped sliding rod 83 to slide out of the guide seat 84, so that the mounting plate 82 moves to the right until the cutting end of the scissors 81 in the mounting plate 82 is located at the position when the U-shaped frame 631 does not move to the right;

during the process of rightward movement of the threaded seat 71, the threaded seat 71 is firstly separated from the first pressure sensor 74, and then is in contact with the sliding seat 77 below the second pressure sensor 75, so as to drive the sliding seat 77 to move upwards and extrude a fourth return spring, so that the sliding seat 77 triggers the second pressure sensor 75, at this time, the second pressure sensor 75 sends a signal to the processor for processing, the processor sends an instruction to the relay, the forward motor is controlled to stop rotating, the second electric telescopic rod 816 is controlled to start at the same time, so that the second electric telescopic rod extends, the first toothed plate 813 is driven to move backwards, the fourth gear 815 drives the second toothed plate 814 to move forwards synchronously, the two extrusion plates 811 are driven to approach synchronously, the two blades are driven to approach mutually, the second return spring is stretched until the two blades shear the heat shrink tube 5, and further, the processor sends an instruction to the relay, and the second electric telescopic rod 816 is controlled to reset;

after the shearing time is over, the processor sends an instruction to the relay, controls the motor to rotate forwards, drives the lead screw 72 to rotate forwards, drives the thread seat 71 to move rightwards, enables the substrate 61 to move rightwards continuously, further drives the heat shrink tube 5 to move rightwards continuously to be close to the data line 3, until the thread seat 71 is in contact with a sliding seat 77 below a third pressure sensor 76, further drives the sliding seat 77 to move upwards, extrudes a fourth reset spring, enables the sliding seat 77 to trigger the third pressure sensor 76, at the moment, the third pressure sensor 76 sends a signal to the processor to be processed, further the processor sends an instruction to the relay, controls the motor to rotate forwards to stop rotating, then controls the first electric telescopic rod 67 to contract for 1/3 distance, enables one of the sliding plates 64 to be far away from the middle of the through hole, further drives the first gear 65 to rotate through a tooth groove of the sliding plate 64, further drives the other first gear 66 to rotate, further drives the other first gear 65 to rotate, further drives the other sliding plate 64 to be far away from the middle of the through hole, further drives two U-shaped frames 631 to be far away from the middle of the through hole synchronously, and at the middle of the through hole, at the first torsion spring shaft, enables the L-shaped clamping plate 631 to be far away from the heat shrink tube 5, and unlocking of the heat shrink tube 631 is achieved; the specific distance of 1/3 is mainly considered from the distance that the L-shaped clamp plate 632 is far away from the heat shrink tube 5 and the distance that the pull plate 68 and the contact 681 are close to the heat shrink tube 5, so that the L-shaped clamp plate 632 can be far away from the heat shrink tube 5, the heat shrink tube 5 is unlocked, meanwhile, the contact 681 is prevented from abutting against the heat shrink tube 5 outside the data line 3, and the contact 681 drives the heat shrink tube 5 to slide out of the data line 3 when the substrate 61 moves to the left; specifically, the shearing time is longer than the extending and shortening time of the second electric telescopic rod 816, and the shearing time can be stored in the processor;

when the unlocking time is up, the processor sends an instruction to the relay, controls the motor to rotate reversely, further drives the screw rod 72 to rotate reversely, further drives the threaded seat 71 to move leftwards, thereby driving the substrate 61 to move leftwards, so that the substrate 61 is far away from the data line 3, in the process that the substrate 61 is far away from the data line 3, the threaded seat 71 is firstly separated from the third pressure sensor 76, then is contacted with the sliding seat 77 below the second pressure sensor 75, further the sliding seat 77 moves upwards, the fourth reset spring is extruded, so that the sliding seat 77 triggers the second pressure sensor 75, at the moment, the second pressure sensor 75 sends a signal to the processor for processing, further the processor sends an instruction to the relay, controls the first electric telescopic rod 67 to contract the remaining 2/3 distance, realizes the reset of the first electric telescopic rod 67, and enables the U-shaped frame 631 and the contact 681 to reset; along with the continuous left movement of the threaded seat 71, the threaded seat 71 is in contact with a sliding seat 77 below the first pressure sensor 74, so that the sliding seat 77 is driven to move upwards, the fourth return spring is extruded, the sliding seat 77 triggers the first pressure sensor 74, the first pressure sensor 74 sends a signal to a processor for processing at the moment, the processor sends an instruction to a relay, the reverse rotation motor is controlled to stop rotating, the two reset U-shaped frames 631 are located at the upper end and the lower end of the heat shrink tube 5, and the two contact heads 681 are located in the middle of the heat shrink tube 5; specifically, the unlocking time is longer than the time that the first electric telescopic rod 67 contracts by 1/3 of the distance, and the unlocking time can be stored in the processor;

when the substrate 61 moves leftwards and returns, the substrate 61 is in contact with the mounting plate 82, so that the mounting plate 82 is driven to move leftwards, the second return spring is extruded, and the scissors 81 are far away from the cutting end of the heat shrink tube 5; further, the treater sends the instruction for the relay, and control conveyer belt 2 starts for 3 data lines that sheathe in 5 pyrocondensation pipes keep away from sleeve pipe mechanism 6, and the next data line 3 of being convenient for is close to sleeve pipe mechanism 6, thereby is convenient for the continuous sleeve pipe work of a plurality of data lines 3.

The above description is only for the preferred embodiment of the present invention, but the scope of the present invention is not limited thereto, and any person skilled in the art should be considered as the technical solutions and the inventive concepts of the present invention within the technical scope of the present invention.

Claims (10)

1. The production sleeve equipment for the hard disk data line is characterized by comprising a base (1), a conveyor belt (2) arranged at the upper right end of the base (1) and a plurality of fixing mechanisms (4) arranged on the conveyor belt (2) and used for clamping the data line (3), wherein the fixing mechanisms (4) are uniformly arranged on the conveyor belt (2), a support (10) is arranged at the upper left end of the base (1), a sleeve mechanism (6) used for sleeving a heat-shrinkable tube (5) outside the data line (3) is arranged on the support (10) in a left-right sliding mode, the sleeve mechanism (6) is driven to move left and right through a moving mechanism (7), a cutting mechanism (8) used for cutting the heat-shrinkable tube (5) is arranged at one end, far away from the data line (3), of the cutting mechanism (6) is provided with a flattening component (9) used for flattening the heat-shrinkable tube (5);

the sleeve mechanism (6) comprises a base plate (61) which is arranged on a support (10) in a left-right sliding mode, a through hole for a heat shrinkable tube (5) and a data line (3) to penetrate through is formed in the middle of the base plate (61), a positioning ring (62) is embedded in the inner wall of the through hole, clamping assemblies (63) for clamping the upper end and the lower end of the heat shrinkable tube (5) are symmetrically arranged at the upper end and the lower end of the through hole, sliding plates (64) are arranged at the ends, deviating from each other, of the two clamping assemblies (63), the ends, deviating from each other, of the two sliding plates (64) penetrate through the inner wall of the positioning ring (62) in a vertical sliding mode, one end, far away from the clamping assembly (63), of any one positioning ring (62) is installed with the movable end of a first electric telescopic rod (67), and the fixed end of the first electric telescopic rod (67) is fixedly connected with the inner wall of the base plate (61); one side of each of the two sliding plates (64) is connected with a first gear (65) in a meshed mode, the two first gears (65) are connected with the inner wall of the base plate (61) in a rotating mode, tooth grooves meshed with the two first gears (65) are formed in the surfaces of the two sliding plates (64) respectively, the two first gears (65) are arranged in a left-right staggered mode, the two first gears (65) are connected with an inner gear (66) in a meshed mode, and the inner gear (66) is connected with the inner wall of the base plate (61) in a rotating mode;

the clamping assembly (63) comprises a U-shaped frame (631) installed at the end part of a sliding plate (64), wherein L-shaped clamping plates (632) are arranged at the front end and the rear end of the inner wall of the U-shaped frame (631) in a rotating mode through a first torsion spring shaft, a first wire roller (633) is fixedly installed at one end, far away from the two L-shaped clamping plates (632), of the two first torsion spring shafts, a connecting wire (635) is wound on the surface of the first wire roller (633), one movable end of the connecting wire (635) is fixed on the surface of the first wire roller (633), guide wheels (634) are arranged at the front end and the rear end of the outer wall of the U-shaped frame (631), the other movable end of the connecting wire (635) penetrates through the guide wheels (634) to be fixed on the surface of a second wire roller (636), a mounting shaft of the second wire roller (636) is fixed at the end part of a sliding frame (637), the sliding frame (637) is arranged on the surface of a fixed cover (638), one end, far away from the second wire roller (636) is fixedly connected with the inner wall of a positioning ring (62), and two sliding plates (64) penetrate through the inner wall of the fixed cover (638) and a first return spring (637);

the front end and the rear end of the through hole are symmetrically provided with pull plates (68), one ends, close to each other, of the two pull plates (68) are rotatably connected with contact heads (681) through second torsion spring shafts, the two contact heads (681) are respectively contacted with the inner walls of the front end and the rear end of the heat shrink tube (5), one ends, away from each other, of the two pull plates (68) slide back and forth to penetrate through the inner wall of the positioning ring (62), one sides of the two pull plates (68) are respectively connected with second gears (69) in a meshed mode, the two second gears (69) are respectively connected with the inner wall of the base plate (61) in a rotated mode, tooth blocks meshed with the two second gears (69) are respectively arranged on the surfaces of the two pull plates (68), one ends, away from the tooth blocks, of the two second gears (69) are respectively connected with third gears (610) in a meshed mode, the two third gears (610) are respectively connected with the inner wall of the base plate (61) in a rotated mode, and the two third gears (610) are arranged in a vertically staggered mode;

the end of the contact head (681) far away from the pulling plate (68) is triangular.

2. The production casing equipment for the hard disk data line according to claim 1, wherein the moving mechanism (7) comprises a threaded seat (71) arranged at the top end of the base plate (61) and a screw rod (72) matched with the threaded seat (71), the screw rod (72) is rotatably arranged in the positioning seat (73), the screw rod (72) is driven by a motor, a through groove for the threaded seat (71) to slide left and right is formed in the bottom end of the threaded seat (71), and the left end of the positioning seat (73) is fixedly connected with the bracket (10) through a vertical plate (101).

3. The hard disk data line production casing pipe device according to claim 2, wherein the cutting mechanism (8) comprises a mounting plate (82) and a pair of scissors (81) arranged at the top end of the support (10) in a left-right manner, the scissors (81) are used for cutting the heat shrink tube (5), a through opening is formed in the middle of the mounting plate (82), a rotating shaft at the rotating position of the scissors (81) is fixedly connected with the inner wall of the through opening, the tops of two blades in the scissors (81) are respectively abutted to two extrusion plates (811), the two extrusion plates (811) are located at the extreme positions of the two blades when the scissors (81) are not closed, one ends, far away from the blades, of the two extrusion plates (811) are arranged in the fixing seat (812) in a front-back sliding manner, one ends, far away from the blades, of the two extrusion plates (811) are respectively connected with the bottom ends of the first toothed plate (813) and the second toothed plate (814), the first toothed plate (813) and the second toothed plate (814) are arranged in a staggered manner, a fourth gear (815) is engaged with one end, which is connected with the first toothed plate (813) and one end of the second toothed plate (816), and one end, the other end of the second toothed plate (816) is connected with the electric telescopic rod (816), and the electric telescopic rod (816) is arranged in the fixing seat (816), extension plates (817) are arranged at the front end and the rear end of the fixed seat (812), second reset springs are arranged between the two extension plates (817) and the two blades respectively, and the fixed seat (812) is fixedly arranged in the through opening;

the left upper and lower both ends of mounting panel (82) are all fixed and are provided with T form slide bar (83), two T form slide bar (83) are pegged graft with the inner wall slip of two guide holder (84) respectively, guide holder (84) are fixed to be inlayed and are located riser (101), and are provided with third reset spring, two between the inner wall of T form slide bar (83) and guide holder (84) T form slide bar (83) and scissors (81) crisscross setting.

4. The hard disk data line production casing device according to claim 3, wherein a first pressure sensor (74), a second pressure sensor (75) and a third pressure sensor (76) are sequentially arranged on the inner wall of the top end of the fixed seat (812) from left to right, the first pressure sensor (74) and the threaded seat (71) are fixedly mounted, a sliding seat (77) is fixedly mounted on the top ends of the second pressure sensor (75) and the third pressure sensor (76), a sliding groove for sliding the sliding seat (77) is formed in the top of the threaded seat (71), a positioning plate (78) is arranged on the top end of the threaded seat (71), the sliding seat (77) is fixed with the positioning plate (78) through a fixing bolt, threaded holes matched with the fixing bolt are formed in the sliding seat (77) and the positioning plate (78), the number of the threaded holes in the positioning plate (78) is multiple, and the first pressure sensor (74), the second pressure sensor (75) and the third pressure sensor (76) are electrically connected with a control panel.

5. The hard disk data line production casing device according to claim 4, wherein one end of each of the first pressure sensor (74), the second pressure sensor (75) and the third pressure sensor (76) close to the threaded seat (71) is provided with a sliding cover (79), and fourth return springs are respectively arranged between the inner walls of the three sliding covers (79) and the first pressure sensor (74), the second pressure sensor (75) and the third pressure sensor (76).

6. The production sleeve equipment for the hard disk data line according to claim 5, wherein the fixing mechanism (4) comprises a T-shaped lower seat (41) arranged on the conveyor belt (2) and an upper seat (42) rotatably arranged on the T-shaped lower seat (41) through a hinge, a placing groove for placing the data line (3) is formed in one end of the T-shaped lower seat (41) close to one end of the upper seat (42), lug plates are arranged at one ends of the T-shaped lower seat (41) and the upper seat (42) far away from the hinge, the two lug plates are symmetrically arranged up and down, and the two lug plates are fixed through locking bolts;

the lower part of the T-shaped lower seat (41) is provided with a bearing plate (43) in a left-right sliding mode, and a fifth return spring is arranged between the bearing plate (43) and the inner wall of the T-shaped lower seat (41).

7. The hard disk data line production casing device according to claim 6, wherein the lower left end of the T-shaped base (41) is embedded with an infrared emitter, the right end of the base plate (61) is embedded with an infrared receiver matched with the infrared emitter, and the infrared receiver is electrically connected with the control panel.

8. The hard disk data line production casing device according to claim 7, wherein the control panel is installed in a support (10), a processor and a relay are installed in the control panel, the output ends of the first pressure sensor (74), the second pressure sensor (75), the third pressure sensor (76) and the infrared receiver are all electrically connected with the input end of the processor, the output end of the processor is electrically connected with the input end of the relay, and the output end of the relay is respectively electrically connected with the motor, the first electric telescopic rod (67) and the second electric telescopic rod (816).

9. The production casing device for the hard disk data line according to claim 2, wherein a line passing hole for the heat shrinkable tube (5) to pass through is formed in the vertical plate (101), guide pieces (85) abutted to the front end and the rear end of the heat shrinkable tube (5) are fixedly mounted on the front inner wall and the rear inner wall of the line passing hole, the guide pieces (85) extend out of the right end of the line passing hole, and a gap is reserved between the right end of the guide pieces (85) and the shearing end of the heat shrinkable tube (5).

10. The hard disk data line production casing pipe device according to claim 9, wherein the flattening assembly (9) comprises two side plates (91) arranged at the left end of the vertical plate (101), the two side plates (91) are positioned at the upper end and the lower end of the line through hole, two groups of pressing roller sets are arranged between the adjacent ends of the two side plates (91) from left to right, the pressing roller sets are specifically two rotating rollers (92), and the two rotating rollers (92) are arranged in front of and behind each other.

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