CN109605728B - Welding heat shrinkage mechanism and welding heat shrinkage method for middle-portion electrified conducting wire - Google Patents

Abstract

The invention provides a welding heat shrinkage mechanism and a welding heat shrinkage method for a wire with a resistor in the middle, and belongs to the technical field of machinery. The problem that automatic welding and thermal shrinkage coating cannot be carried out on a middle-portion resistor wire in the prior art is solved. This welding pyrocondensation mechanism of electrified wire in middle part, but including the frame with set up the intermittent type pivoted decollator carousel in the frame, be fixed with a plurality of decollator clamp that can open and shut along its circumference on the decollator carousel, welding pyrocondensation mechanism still has set gradually first wire feeding mechanism, power transmission resistance mechanism, second wire feeding mechanism, resistance sleeve feeding mechanism and resistance sleeve pyrocondensation mechanism in the frame and along the direction of rotation of decollator carousel, and it can realize automated production, and production efficiency is high.

Description

Welding heat shrinkage mechanism and welding heat shrinkage method for middle-portion electrified conducting wire

Technical Field

The invention belongs to the technical field of machinery, and relates to a welding machine, in particular to a welding heat shrinkage mechanism with a charged wire in the middle and a welding heat shrinkage method.

Background

Holiday colored lamps require a large number of wire segments to be connected with a large number of LED lamps or rice bubbles to form a string of lamps. The existing wires in the market are long wires in bundles, and the purchased wires are cut into wire sections with required lengths. Currently, mechanisms on the market for processing wire segments typically include a wire feed assembly, and a wire clamping assembly that mates with the wire feed assembly. After the wire section is processed and formed, the wire section and the LED lamp or the rice bulb are welded together through a welding mechanism, and only the welding is insufficient, a plastic heat shrinkage pipe is sleeved at the welding position, the plastic heat shrinkage pipe is a plastic mould pipe, the mould pipe is heated and deformed after being sleeved, and the plastic heat shrinkage pipe is cooled to enable the plastic heat shrinkage pipe to be fastened and sleeved at the welding position, and particularly, the existing welding equipment can only realize the welding of the LED lamp or the rice bulb and the wire end, but cannot realize the automatic welding and the heat shrinkage operation of the resistor on the wire, and particularly cannot realize the welding and the heat shrinkage operation of the wire section with the resistor in the middle part on the double-wire LED bulb as shown in fig. 1.

Disclosure of Invention

The invention aims at solving the problems in the prior art, and provides a welding heat shrinkage mechanism and a welding heat shrinkage method for a wire with a resistor in the middle, which aims at solving the technical problems of realizing automatic welding and heat shrinkage operation of the wire with the resistor in the middle.

The aim of the invention can be achieved by the following technical scheme: the utility model provides a hot shrink mechanism of welding of electrified wire in middle part, includes the frame and sets up the rotatable decollator carousel of intermittent type in the frame, be fixed with a plurality of decollator clamp that can open and shut along its circumference on the decollator carousel, its characterized in that, the hot shrink mechanism of welding still includes setting up in the frame and along the rotation direction of decollator carousel first send line mechanism, power transmission resistance mechanism, second send line mechanism, resistance bush feeding mechanism and resistance bush pyrocondensation mechanism that set gradually, first line mechanism is used for sending into the decollator clamp with first wire section, power transmission resistance mechanism is used for connecting the resistance on first wire section, second send line mechanism is used for connecting the second wire section on the resistance, resistance bush feeding mechanism is used for establishing resistance bush pipe on the connecting portion of resistance and first wire section and second wire section, resistance bush pyrocondensation mechanism is used for carrying out the pyrocondensation with resistance bush.

In the welding pyrocondensation mechanism of middle part electrified wire, the power transmission resistance mechanism includes resistance case, resistance conveying subassembly, cutter subassembly and resistance and advances the subassembly, resistance conveying subassembly is led in the resistance by resistance case, and resistance conveying subassembly is including being used for with the fixed knife strip seat of cutter subassembly looks adaptation and being used for driving the conveyer that the resistance removed on fixed knife strip seat, resistance advances the subassembly and is including being used for sending the electric resistance clamp on the decollator carousel with the resistance after cutting. The resistor after cutting is positioned on the radial direction of the divider turntable, and the conveying part is a power transmission resistance toothed plate with a plurality of teeth which are upwards arranged.

In the welding heat shrinkage mechanism with the electric lead in the middle part, the cutter assembly comprises a resistance cutter, a resistance cutter seat and a swing arm for driving the resistance cutter to swing on the resistance cutter seat, and the resistance cutter seat is fixedly connected to the fixed cutter strip seat. The swing arm and the cutter are both positioned on one side of the fixed resistor strip seat, which is sent out by the resistor, and the swing arm drives the cutter to swing from bottom to top so as to cut a lead at the end part of the resistor.

In the welding thermal shrinkage mechanism with the electric lead in the middle part, the resistance feeding component further comprises a resistance feeding slide rail, a resistance feeding slide block and a resistance feeding clamp seat, wherein the resistance feeding slide block is connected to the resistance feeding slide rail in a sliding mode, and the resistance feeding clamp seat is fixedly connected to the resistance feeding slide block.

In the welding heat shrinkage mechanism with the electric wires in the middle part, the welding machine further comprises a waste blowing air pipe connected to the frame, and an air blowing port of the waste blowing air pipe faces to the resistor connected with the second electric wire.

In the welding heat shrinkage mechanism with the electric wires in the middle part, the electric resistance sleeve feeding mechanism comprises a first electric resistance sleeve feeding component for transferring the electric resistance sleeve to the second wire section and a second electric resistance sleeve feeding component for moving the electric resistance sleeve from the second wire section to the connecting part of the electric resistance and the first wire section and the second wire section, the first electric resistance sleeve feeding component comprises a first electric resistance sleeve clamp and a driving piece for driving the first electric resistance sleeve clamp to work, and the second electric resistance sleeve feeding component comprises a second electric resistance sleeve clamp and a driving piece for driving the second electric resistance sleeve clamp to work.

In the welding heat shrinkage mechanism with the electric wires in the middle part, a first wire stripping mechanism is arranged between the first wire feeding mechanism and the electric wire transmission resistance mechanism.

The welding method of the welding heat shrinkage mechanism applied to the middle-part resistance wire is characterized by comprising the following steps of:

step a, connecting a resistor with an inner end wire: clamping the first wire segment onto a divider clamp, and then welding the inner end of the resistor with the first wire segment;

step b, connecting the resistor with an outer end wire: welding the inner end of the second wire segment at the outer end of the resistor;

step c, feeding the resistor sleeve: transferring the resistor sleeve to the connection part of the resistor, the first wire segment and the second wire segment;

step d, thermal shrinkage of the resistance sleeve: and (3) heat-shrinking the resistance sleeve on the connecting part of the resistor and the first wire section and the second wire section.

In the above welding method applied to the welding heat shrinkage mechanism of the wire with the resistor in the middle, the position of the wire is adjusted by the wire lifting element between the step b and the step c.

In the above welding method applied to the welding heat shrinkage mechanism with the resistor wire in the middle, the step c includes a step c1 and a step c2, wherein the step c1 is to transfer the resistor sleeve to the second wire segment, and the step c2 is to transfer the resistor sleeve from the second wire segment to the connection part between the resistor and the first wire segment and the second wire segment.

Compared with the prior art, the invention can realize the automatic welding of the wire segment with the resistor in the middle and the automatic thermal shrinkage operation on the connecting welding point of the resistor and the wire segment, and has good precision and high working efficiency.

Drawings

Fig. 1 is a two-wire LED block diagram without heat shrink.

Fig. 2 is a schematic diagram of a two-wire LED resistance sleeve welder with the present invention.

Fig. 3 is a schematic view of the structure of the divider pliers of the present invention.

Fig. 4 is a schematic structural view of a first wire feeding mechanism in the present invention.

Fig. 5 is a schematic diagram of the structure of the power transmission resistor mechanism in the present invention.

Fig. 6 is a schematic structural view of a second wire feeding mechanism in the present invention.

Fig. 7 is a schematic view of the structure of the resistor sleeve feeding mechanism in the present invention.

Fig. 8 is a finished view of the processed product of the present invention.

In the figure, 1, a rack; 2. a divider carousel; 3. divider clamp; 301. a first jaw; 302. a second jaw; 4. a first wire feeding mechanism; 401. a first incoming line motor; 402. a first solder feeding assembly; 404. a first wire feeding and leading nozzle; 405. a first incoming wire stripping assembly; 5. a power transmission resistance mechanism; 501. a resistor storage box; 502. a fixed knife strip seat; 503. a transfer member; 504. a power transmission resistor clamp; 505. a resistor cutter; 506. a resistor cutter holder; 507. swing arms; 508. a power transmission resistance slide rail; 509. a power transmission resistance slider; 510. a resistor feeding clamp seat; 6. a second wire feeding mechanism; 601. a second incoming line motor; 602. a second solder feeding assembly; 603. the second incoming line sliding rail assembly; 604. a second wire feeding and leading nozzle; 605. a second incoming wire stripping assembly; 606. a second incoming solder clamp assembly; 607. a second incoming wire waste bin; 7. a resistor sleeve feeding mechanism; 701. a first resistive casing clamp; 702. a second resistance sleeve clamp; 8. a resistance sleeve thermal shrinkage mechanism; 9. a third wire feeding mechanism; 10. a double sleeve feed mechanism; 11. a welding bubble mechanism; 12. a double-sleeve thermal shrinkage mechanism; 13. a double-wire cutting mechanism; 14. a double sleeve adjusting mechanism; 15. a first wire stripping mechanism; 16. a second wire stripping mechanism; 17. a wire pulling mechanism; 18. a detection mechanism; 19. blowing a waste gas pipe; 20. a wire feed mechanism; 21. a wire lifting member; 2101. a fixed rod; 2102. lifting the wire; 22. an LED bulb; 23. a first wire segment; 24. a second wire segment; 25. a third wire segment; 26. a resistor; 27. a resistive bushing; 28. and welding a bulb sleeve.

Detailed Description

The following are specific embodiments of the present invention and the technical solutions of the present invention will be further described with reference to the accompanying drawings, but the present invention is not limited to these embodiments.

Referring to fig. 2-7, the present embodiment is a welding heat shrinking mechanism with a resistance wire in the middle part applied to a double-wire LED resistance tube welding machine, the double-wire LED resistance tube welding machine comprises a frame 1, a divider rotary table 2 capable of intermittently rotating is arranged on the frame 1, a plurality of divider clamps 3 capable of opening and closing are fixed on the divider rotary table 2 along the circumferential direction of the divider rotary table 2, a first wire feeding mechanism 4, a power transmission resistance mechanism 5, a second wire feeding mechanism 6, a resistance tube feeding mechanism 7, a resistance tube heat shrinking mechanism 8, a wire feeding mechanism 20, a third wire feeding mechanism 9, a double-tube feeding mechanism 10, a double-wire cutting mechanism 13, a welding bulb mechanism 11, a detection mechanism 18, a tube adjusting mechanism 14 and a double-tube heat shrinking mechanism 12 are sequentially arranged on the frame 1 along the rotation direction of the divider rotary table 2, the divider clamp 3 comprises a first jaw 301 and a second jaw 302 capable of respectively clamping two wires, the first wire feeding mechanism 4 is used for feeding the first wire segment 23 into the first jaw 301, the power feeding resistance mechanism 5 is used for connecting the resistor 26 to the first wire segment 23, the second wire feeding mechanism 6 is used for connecting the second wire segment 24 to the resistor 26, the resistor sleeve feeding mechanism 7 is used for sleeving a resistor sleeve on the resistor 26 and the connecting part of the resistor 26 and the first wire segment 23 and the second wire segment 24, the resistor sleeve heat-shrinking mechanism 8 is used for carrying out heat shrinkage on the resistor sleeve 27, the third wire feeding mechanism 9 is used for feeding the third wire segment 25 into the second jaw 302, the double-sleeve feeding mechanism 10 is used for respectively feeding two bulb-welding sleeves 28 to the second wire segment 24 and the third wire segment 25, the bulb-welding mechanism 11 is used for welding the LED bulb 22 with the second wire segment 24 and the third wire segment 25, the double-sleeve heat-shrinking mechanism 12 is used for heat-shrinking two welding bulb sleeves 28 on the connection parts of the LED bulb 22, the second wire segment 24 and the third wire segment 25 respectively.

Further, the first wire feeding mechanism 4 includes a first wire feeding motor 401, a first solder feeding component 402, a first wire feeding sliding rail component, a first wire feeding and leading nozzle 404 and a first wire feeding and leading cutter component 405, the first wire feeding and leading nozzle 404 is connected to the first wire feeding sliding rail component and is driven by the first wire feeding motor 401 to move back and forth, and the first wire feeding and leading cutter component 405 is arranged between the first wire feeding and leading nozzle 404 and the divider turntable 2 and is used for stripping end wire skins of the first wire guiding sections.

Further, the resistor feeding mechanism 5 includes a resistor storage box 501, a resistor transmission assembly, a cutter assembly and a resistor feeding assembly, the resistor transmission assembly is used for guiding resistors from the resistor storage box 501, the resistor transmission assembly includes a fixed knife bar seat 502 adapted to the cutter assembly and a transmission piece 503 for driving the resistors to move on the fixed knife bar seat 502, the resistor feeding assembly includes a resistor feeding clamp 504 for feeding the cut resistors to the divider turntable 2, a resistor feeding slide rail 508, a resistor feeding slide block 509 and a resistor feeding clamp seat 510, the resistor feeding slide block 509 is slidably connected to the resistor feeding slide rail 508, the resistor feeding clamp seat 510 is fixedly connected to the resistor feeding slide block 509, and the resistor feeding clamp 504 is connected to the resistor feeding clamp seat 510; the cutter assembly comprises a resistor cutter 505, a resistor cutter holder 506 and a swing arm 507 for driving the resistor cutter 505 to swing on the resistor cutter holder 506, the resistor cutter holder 506 is fixedly connected to the fixed cutter bar holder 502, the swing arm 507 and the cutter are both positioned on one side of the fixed cutter bar holder 502 from which a resistor is sent out, and the swing arm 507 drives the cutter to swing from bottom to top so as to cut a lead at the end part of the resistor 26.

Further, the resistor feeding assembly further includes a resistor feeding slide rail 508, a resistor feeding slide block 509, and a resistor feeding clamp seat 510, wherein the resistor feeding slide block 509 is slidably connected to the resistor feeding slide rail 508, and the resistor feeding clamp seat 510 is fixedly connected to the resistor feeding slide block 509.

Further, a first wire stripping mechanism 15 is disposed between the first wire feeding mechanism 4 and the power transmission resistor mechanism 5, and the first wire stripping mechanism 15 is used for stripping the outer end wire skin of the first wire segment 23.

A second wire stripping mechanism 16 is arranged between the double-sleeve feeding mechanism 10 and the welding bulb mechanism 11.

Further, the second wire feeding mechanism 6 includes a second wire feeding motor 601, a second solder feeding assembly 602, a second wire feeding sliding rail assembly 603, a second wire feeding wire nozzle 604, a second wire feeding wire stripping assembly 605, a second wire feeding solder clamp assembly 606 and a second wire feeding wire waste drum 607, the second wire feeding wire nozzle 604 is connected to the second wire feeding sliding rail assembly 603, and is driven by the second wire feeding motor 601 to move back and forth, the second wire feeding wire stripping wire nozzle 605 and the second wire feeding wire clamping assembly 606 are arranged between the second wire feeding wire nozzle 604 and the divider turntable 2, and are used for stripping and tin feeding end wire skins of a second wire feeding wire section, and the second wire feeding wire waste drum 607 is used for collecting wire skins stripped by the second wire feeding wire stripping assembly 605.

Further, the welding machine further comprises a waste blowing air pipe 19 connected to the frame 1, and an air blowing port of the waste blowing air pipe 19 faces the resistor connected to the second wire segment 24. Specifically, a reject blowing air pipe 19 is provided at the second wire feeding mechanism 6.

Further, a wire lifting piece 21 is arranged between the second wire feeding mechanism 6 and the resistor sleeve feeding mechanism 7 and between the first resistor sleeve feeding assembly and the second resistor sleeve feeding assembly, the wire lifting piece 21 comprises a fixing rod 2101 which is vertically arranged and a wire lifting steel wire 2102 which is arranged at the top end of the fixing rod 2101, one end of the wire lifting steel wire 2102, which faces the rotating direction of the divider rotary table 2, is provided with a lifting part which is inclined downwards, when the second wire segment 24 sags due to gravity, the wire lifting piece 21 can be used for correcting, so that the first wire segment 23, the resistor 26 and the second wire segment 24 are kept in a horizontal state, and the subsequent resistor sleeve feeding mechanism 7 is more convenient for feeding the resistor sleeve 27.

Further, the resistor sleeve feeding mechanism 7 comprises a first resistor sleeve feeding assembly for transferring the resistor sleeve 27 onto the second wire section 24 and a second resistor sleeve feeding assembly for moving the resistor sleeve 27 from the second wire section 24 onto the connection portion of the resistor and the first wire section 23 and the second wire section 24, wherein the first resistor sleeve feeding assembly comprises a first resistor sleeve clamp 701 and a driving member for driving the first resistor sleeve clamp 701 to operate, and the second resistor sleeve feeding assembly comprises a second resistor sleeve clamp 702 and a driving member for driving the second resistor sleeve clamp 702 to operate, and the driving member is the prior art and is not described herein.

Further, the resistance sleeve thermal shrinkage mechanism 8 includes a blowing barrel for thermal shrinkage through thermal blowing, which is not described in detail herein.

The invention has the advantages that each mechanism is driven by a connecting rod or a motor, the structure is simple, the computer control can be realized, the working efficiency is high, and the working steps are as follows:

step a, connecting a resistor with an inner end wire: clamping the first wire segment 23 onto the divider clamp 3, and then welding the inner end of the resistor 26 with the first wire segment 23;

step b, connecting the resistor with an outer end wire: welding the inner end of the second wire segment 24 to the outer end of the resistor 26;

step c, feeding the resistor sleeve: transferring the resistor sleeve 27 to the connection part of the resistor 26, the first wire segment 23 and the second wire segment 24;

step d, thermal shrinkage of the resistance sleeve: the resistor sleeve 27 is heat shrunk onto the connection of the resistor 26 with the first wire segment 23 and the second wire segment 24.

Further, between step b and step c, the position of the wire is adjusted by the wire position adjusting member.

Further, between the step b and the step c, after the second wire segment 24 is welded on the resistor, the welding effect between the resistor 26 and the first wire segment 23 and between the second wire segment 24 and the resistor 26 is tested by blowing the waste gas pipe 19.

Further, step c includes a step c1 and a step c2, wherein step c1 is to transfer the resistor sleeve 27 onto the second wire segment 24, and step c2 is to transfer the resistor sleeve 27 from the second wire segment 24 onto the connection portion between the resistor 26 and the first wire segment 23 and the second wire segment 24.

The embodiment can realize automatic welding of the wire segment with the resistor in the middle and automatic thermal shrinkage operation on the connecting welding point of the resistor and the wire segment, and the finished product is as shown in fig. 8, and has good precision and high working efficiency.

The specific embodiments described herein are offered by way of example only to illustrate the spirit of the invention. Those skilled in the art may make various modifications or additions to the described embodiments or substitutions thereof without departing from the spirit of the invention or exceeding the scope of the invention as defined in the accompanying claims.

Claims (5)

1. The utility model provides a welding pyrocondensation mechanism of middle part electrified wire, includes frame (1) and sets up on frame (1) but intermittent type pivoted decollator carousel (2), decollator carousel (2) are gone up and are fixed with a plurality of decollator clamp (3) that can open and shut along its circumference, characterized in that, welding pyrocondensation mechanism still includes first wire feeding mechanism (4), power transmission resistance mechanism (5), second wire feeding mechanism (6), resistance bush feed mechanism (7) and resistance bush pyrocondensation mechanism (8) that set gradually on frame (1) and along the direction of rotation of decollator carousel (2), first wire feeding mechanism (4) are used for sending into decollator clamp (3) with first wire segment (23), power transmission resistance mechanism (5) are used for connecting resistance (26) on first wire segment (23), second wire feeding mechanism (6) are used for connecting second wire segment (24) on resistance bush (26), resistance bush feed mechanism (7) are used for setting resistance bush (27) on resistance bush (26) and resistance bush (24) and first wire segment (24) and resistance bush (27) are used for carrying out thermal shrinkage (501) and are connected with resistance bush (7) and resistance bush (5) including power transmission mechanism (501) and resistance bush part (5) are used for carrying out thermal shrinkage, including carrying out thermal shrinkage mechanism (501) and carrying out thermal shrinkage part (7) The resistor conveying assembly is guided into the resistor by the resistor storage box (501), the resistor conveying assembly comprises a fixed knife strip seat (502) which is matched with the cutter assembly and a conveying piece (503) which is used for driving the resistor (26) to move on the fixed knife strip seat (502), the resistor conveying assembly comprises an electric transmission resistor clamp (504) which is used for transferring the cut resistor (26) to the divider turntable (2), the resistor sleeve conveying mechanism (7) comprises a first resistor sleeve conveying assembly which is used for transferring the resistor sleeve (27) to the second wire section (24) and a second resistor sleeve conveying assembly which is used for moving the resistor sleeve (27) to a connecting part of the resistor and the first wire section (23) and the second wire section (24), the first resistor sleeve conveying assembly comprises a first resistor sleeve clamp (701) and a driving piece which is used for driving the first resistor sleeve clamp (702) to work, and the second resistor sleeve conveying assembly comprises a second resistor clamp (702) and a driving piece which is used for driving the second resistor clamp (702) to work.

2. The welding heat shrinkage mechanism for the middle-portion electrified wire according to claim 1, wherein the cutter assembly comprises a resistor cutter (505), a resistor cutter seat (506) and a swing arm (507) for driving the resistor cutter (505) to swing on the resistor cutter seat (506), the resistor cutter seat (506) is fixedly connected to the fixed cutter strip seat (502), the swing arm (507) and the cutter are both positioned on one side of the fixed cutter strip seat (502) from which a resistor is sent out, and the swing arm (507) drives the cutter to swing from bottom to top so as to cut the wire at the end of the resistor (26).

3. The welding heat shrinkage mechanism with the middle part provided with a power conducting wire according to claim 2, wherein the resistor feeding component further comprises a resistor feeding slide rail (508), a resistor feeding slide block (509) and a resistor feeding clamp seat (510), the resistor feeding slide block (509) is slidably connected to the resistor feeding slide rail (508), the resistor feeding clamp seat (510) is fixedly connected to the resistor feeding slide block (509), and the resistor feeding clamp (504) is connected to the resistor feeding clamp seat (510).

4. Welding heat-shrink mechanism with electrical conductor in the middle part according to claim 1, characterized in that it further comprises a waste-blowing air pipe (19) connected to the frame (1), the air-blowing mouth of the waste-blowing air pipe (19) facing the resistor (26) after the connection of the second conductor segment (24).

5. Welding heat shrink mechanism for middle part electrified wire according to claim 1, characterized in that a first wire stripping mechanism (15) is arranged between the first wire feeding mechanism (4) and the electric resistance transmission mechanism (5).