CN114955715B

CN114955715B - Wire collecting device for welding wire production

Info

Publication number: CN114955715B
Application number: CN202210758010.6A
Authority: CN
Inventors: 殷俊; 旷伟锋; 肖亮
Original assignee: Hunan Huite Welding Materials Technology Co ltd
Current assignee: Hunan Huite Welding Materials Technology Co ltd
Priority date: 2022-06-30
Filing date: 2022-06-30
Publication date: 2023-07-28
Anticipated expiration: 2042-06-30
Also published as: CN114955715A

Abstract

The invention discloses a wire collecting device for welding wire production, wherein a first rotating shaft of an I-shaped wheel is vertically embedded into a first through hole before wire collection is started, then a first rotating block is rotated to enable the first rotating shaft to be in a horizontal state, a sliding seat is slid to enable a second rotating shaft to be embedded into a second through hole, and then a first motor is started to drive a rotary drum to rotate, so that welding wire collection is realized; after the wire winding is completed, the sliding seat slides again to enable the second rotating shaft to be pulled away from the second through hole, then the first rotating block can be rotated to enable the spool to return to the vertical state, and then the whole spool is disassembled to directly finish the blanking of the welding wire; the step of detaching the winding drum from the spool is omitted, and the first rotating shaft and the second rotating shaft can be directly packaged and transported after being detached from the winding drum; the whole production process does not need to set additional installation equipment and installation personnel, so that the production cost is reduced, and the energy conservation and synergy in the production and manufacturing process are facilitated.

Description

Wire collecting device for welding wire production

Technical Field

The invention relates to the technical field of welding wire production, in particular to a wire collecting device for welding wire production.

Background

In the production and manufacturing flow of welding wires, wire winding is an important process; the produced welding wires are orderly wound through a wire winding machine; the existing wire winding machine mainly comprises a spool fixed on a wire winding machine body, wherein a winding drum is sleeved in the middle of the spool; and then the spool is driven to rotate so as to wind the welding wire layer on the winding drum of the spool, and the spool keeps a certain rotating speed in the process so as to stably work.

In the actual production operation process, after the spool finishes winding of the welding wire, the spool still needs to be detached from the spool to realize blanking of the welding wire, the detachment process is very complicated, and the detached spool still needs to be provided with baffle plates at two sides for delivery and transportation, so that additional installation equipment and installation personnel are needed to be arranged, the production cost is increased, and the energy conservation and efficiency improvement in the production and manufacturing process are not facilitated.

Disclosure of Invention

The invention mainly aims to provide a wire collecting device for welding wire production, and aims to solve the problems that the existing wire collecting device needs to detach a winding drum from an spool after the winding of welding wires is completed, is very complicated, increases production cost and is not beneficial to energy conservation and efficiency improvement in the production and manufacturing process.

In order to achieve the above purpose, the technical scheme provided by the invention is as follows:

a wire collecting device for welding wire production comprises a base, a spool, a first rotating block, a disc, a sliding seat, a rotating drum and a first motor; the base is horizontally arranged; the spool comprises a winding drum, a first rotating shaft and a second rotating shaft; the first rotating shaft and the second rotating shaft are respectively detachably arranged at two ends of the winding drum; the central axis of the winding drum, the central axis of the first rotating shaft and the central axis of the second rotating shaft are collinear; the first rotating block is rotatably arranged on the upper surface of the base;

the disc is rotationally embedded in the first rotating block; the disc is provided with a first through hole in a penetrating way, and the first through hole is used for being embedded into the first rotating shaft; the rotating shaft of the first rotating block is perpendicular to the rotating shaft of the disc, and the rotating shaft of the first rotating block is horizontally arranged; the sliding seat is horizontally arranged on the upper surface of the base in a sliding manner, and the sliding direction of the sliding seat is perpendicular to the rotating shaft of the first rotating block; the rotary drum is rotatably arranged on the sliding seat, and a second through hole for being embedded into the second rotating shaft is formed in the rotary drum in a penetrating manner; the first rotating block can rotate until the central axis of the first through hole is in a horizontal state; when the central axis of the first through hole is in a horizontal state, the central axis of the first through hole and the central axis of the second through hole are collinear; the first motor is arranged on the sliding seat and used for driving the rotary drum to rotate.

Preferably, the device further comprises a first supporting arm, a second supporting arm and an electromagnet; the first support arm and the second support arm are both arranged on the upper surface of the base; the first rotating block is rotatably arranged between the first supporting arm and the second supporting arm; the first rotating block is connected with a first abutting plate; the electromagnet is arranged on the upper surface of the base; the electromagnet is used for attracting the first abutting plate; when the electromagnet is attracted to the first abutting plate, the first abutting plate is in a horizontal state, and the central axis of the first through hole is vertically arranged.

Preferably, the device further comprises a stop block arranged on the upper surface of the base and a second abutting plate connected with the first rotating block; the second abutting plate is parallel to the first abutting plate; when the electromagnet attracts the first abutting plate, the second abutting plate is positioned on one side of the first abutting plate, which is close to the sliding seat; the stop block is positioned between the first support arm and the second support arm, the stop block comprises a stop wall which is vertically arranged, and the stop wall faces the sliding seat; the first rotating block can rotate until the second abutting plate abuts against the blocking wall; when the second abutting plate abuts against the blocking wall, the second abutting plate is vertically arranged, and the central axis of the first through hole is horizontally arranged.

Preferably, the first rotating block is provided with a third through hole in a penetrating way; the third through hole is embedded with a first bearing; the disc is embedded in the first bearing; the first through hole is a circular hole, and the first rotating shaft is a circular shaft which is embedded with the first through hole in a matching way; the upper surface of the sliding seat is provided with a supporting seat; the support seat is horizontally provided with a fourth through hole in a penetrating way; a second bearing is embedded in the fourth through hole; the rotary drum is embedded in the second bearing; the rotary drum is coaxially sleeved with a first outer gear ring; an output shaft of the first motor is coaxially connected with a first gear; the first gear is meshed with the first outer gear ring; the second through hole is a rectangular hole; the cross section of the tail end of the second rotating shaft is rectangular and embedded with the second through hole in a matching mode.

Preferably, the device further comprises a limiting assembly; the limiting assembly comprises a U-shaped plate, a rotating column, a connecting cylinder, a third bearing and a limiting plate; the first swivel block includes a first wall and a second wall parallel to each other, and a third wall between the first wall and the second wall; the first abutting plate is connected to the first wall; the second abutting plate is connected to the second wall; the U-shaped plate is connected to the third wall; the U-shaped plate comprises a support plate parallel to the first abutting plate;

The supporting plate is provided with a first threaded hole in a penetrating mode; the first threaded hole and the first through hole share a central axis; the outer wall of the rotary column is provided with external threads which are matched with the first threaded hole in a screwing mode; the rotary column is rotatably arranged through the first threaded hole; a groove is formed in one end, close to the first through hole, of the rotary column; the groove is embedded with the third bearing; the connecting cylinder is embedded in the third bearing; the limiting plate is connected to one end, close to the first through hole, of the connecting cylinder; the connecting cylinder and the first through hole share a central axis; the limiting plate is perpendicular to the central axis of the connecting cylinder; the limiting plate is used for abutting the end face, far away from the winding drum, of the first rotating shaft.

Preferably, the limiting assembly further comprises a limiting post, a first limiting rod and a second limiting rod; the limiting column is connected to one side, facing the first through hole, of the limiting plate; the limiting column and the connecting cylinder share the central axis; the first limiting rod and the second limiting rod are respectively connected to two sides of the outer wall of the limiting column; the central axis of the first limiting rod and the central axis of the second limiting rod are collinear; the end face, far away from the winding drum, of the first rotating shaft is provided with a circular groove; the depth of the circular groove is consistent with the length of the limit column;

The central axis of the circular groove is collinear with the central axis of the first rotating shaft; the inner wall of the circular groove is provided with a first long groove, a second long groove, a first arc-shaped groove and a second arc-shaped groove, wherein the first long groove and the second long groove are opposite to each other, the first arc-shaped groove is communicated with the first long groove, and the second arc-shaped groove is communicated with the second long groove; the distance between the first arc-shaped groove and the end face, far away from the winding drum, of the first rotating shaft is consistent with the distance between the second arc-shaped groove and the end face, far away from the winding drum, of the first rotating shaft; the distance between the first arc-shaped groove and the end face, far away from the winding drum, of the first rotating shaft is consistent with the distance between the first limiting rod and the limiting plate; the distance between the second arc-shaped groove and the end face, far away from the winding drum, of the first rotating shaft is consistent with the distance between the second limiting rod and the limiting plate; the first limiting rod is used for being embedded into the first arc-shaped groove, and the second limiting rod is used for being embedded into the second arc-shaped groove.

Preferably, the device further comprises a first sliding rail, a second sliding rail, a first screw rod, a connecting block and a second motor; the first sliding rail and the second sliding rail are arranged on the upper surface of the base; the first sliding rail is parallel to the second sliding rail; the sliding seat is connected with the first sliding rail and the second sliding rail in a sliding manner; the length direction of the first sliding rail is parallel to the central axis of the rotary drum; the first screw rod is rotatably arranged on the upper surface of the base; the connecting block is connected to the bottom of the sliding seat; the first screw rod is positioned between the first sliding rail and the second sliding rail; the second motor is arranged on the upper surface of the base and used for driving the first screw rod to rotate; the first screw rod is parallel to the first sliding rail; the connecting block is provided with a second threaded hole which is screwed with the screw rod in a matched manner; the screw rod is matched with and penetrates through the second threaded hole.

Preferably, the device further comprises a fixing assembly; the fixing assembly comprises a second rotating block, a supporting block, a bearing plate, a fixing plate, a spring, a wedge-shaped extrusion block and a driving part; the bearing plate is arranged on the upper surface of the base, and the length direction of the bearing plate is consistent with the moving direction of the sliding seat; the bearing plate is arranged close to the sliding seat; the supporting block is arranged on the upper surface of the bearing plate; the second rotating block is rotatably arranged on the supporting block; the rotating shaft of the second rotating block is parallel to the length direction of the bearing plate; the fixed plate is connected to the second rotating block; the length direction of the fixing plate is parallel to the length direction of the bearing plate;

the fixed plate is positioned on one side of the second rotating block, which is far away from the bearing plate; one end of the spring is connected with the second rotating block, and the other end of the spring is connected with the bearing plate; the spring is in a stretching state, so that the second rotating block has a tendency of driving the fixed plate to rotate in a direction away from the sliding seat; the wedge-shaped extrusion block is embedded between the bearing plate and the second rotating block in a sliding manner; the driving component is used for driving the wedge-shaped extrusion block to horizontally move; the wedge-shaped extrusion block is used for being in surface contact with and abutting against the second rotating block so as to keep the fixing plate horizontal; when the fixing plate is kept horizontal, the fixing plate is abutted to the upper surface of the sliding seat, and the upper surface of the sliding seat is horizontally arranged.

Preferably, the wedge-shaped extrusion block comprises a fourth wall which is horizontally arranged and a fifth wall which is obliquely arranged; the side of the fifth wall, which is far away from the sliding seat, is higher than the side, which is close to the sliding seat; the second rotating block comprises a sixth wall for abutting contact with the fifth wall;

the driving part comprises a second screw rod, a nut sleeve, a connecting seat, a second external gear ring, a third motor and a positioning rod; the second screw rod is horizontally connected with one end, far away from the sliding seat, of the wedge-shaped extrusion block; the second screw rod is provided with a through groove; the cross section of the through groove is rectangular; the positioning rod is horizontally and fixedly connected to the upper surface of the base, and the cross section of the positioning rod is rectangular; the positioning rod is matched and slidably embedded with the through groove; the central axis of the second screw rod is perpendicular to the sliding direction of the sliding seat; the nut sleeve is sleeved on the second screw rod in a matched manner; the second outer gear ring is fixedly sleeved on the outer wall of the nut sleeve; the connecting seat is connected to the upper surface of the base, and a fourth bearing is embedded in the connecting seat in a rotating way; the nut sleeve is fixedly embedded in the inner ring of the fourth bearing, and the second screw rod and the fourth bearing share the central axis; the second external gear ring and the second screw rod share a central axis; the third motor is arranged on the upper surface of the base and used for driving the second outer gear ring to rotate so as to drive the second screw rod to horizontally move and drive the wedge-shaped extrusion block to horizontally move.

Preferably, the spool further comprises a first baffle and a second baffle; the first baffle plate is arranged on one side of the winding drum, which is close to the first rotating shaft, the second baffle plate is arranged on one side of the winding drum, which is close to the second rotating shaft, and the first baffle plate is parallel to the second baffle plate.

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

the wire collecting device for welding wire production provided by the invention can more conveniently and rapidly discharge the welding wire after winding; specifically, a first rotating shaft of the spool is vertically embedded into a first through hole before winding is started, then a first rotating block is rotated, so that the first rotating shaft is in a horizontal state, then a sliding seat is slid, so that the sliding seat slides towards a direction close to a second rotating shaft, finally the second rotating shaft is embedded into a second through hole, then a first motor can be started to drive a rotary drum to rotate, thereby driving the spool to rotate, further winding of welding wires is realized, after winding is completed, the sliding seat is slid again, so that the sliding seat moves towards a direction far away from the second rotating shaft, finally the second rotating shaft is pulled out of the second through hole, then the first rotating block can be rotated, the spool returns to a vertical state, then the first rotating shaft can be pulled out of the first through hole, thus the whole spool is detached, blanking of the welding wires can be directly completed, a step of detaching the spool from the spool is omitted, and then the first rotating shaft and the second rotating shaft are detached from the spool to be directly packaged and transported; the whole production process does not need to set additional installation equipment and installation personnel, so that the production cost is reduced, and the energy conservation and synergy in the production and manufacturing process are facilitated.

Drawings

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

FIG. 1 is a schematic diagram of an embodiment of a wire winding device for welding wire production according to the present invention;

FIG. 2 is a schematic view showing another state of a wire winding device for welding wire production according to an embodiment of the present invention;

FIG. 3 is an enlarged schematic view of a detail B in FIG. 1;

FIG. 4 is an enlarged schematic view of a detail A in FIG. 1;

FIG. 5 is an enlarged schematic view of detail C in FIG. 4;

FIG. 6 is a schematic view of a limiting assembly and a first rotating shaft of an embodiment of a wire winding device for welding wire production according to the present invention;

FIG. 7 is a schematic structural view of a fixing assembly of an embodiment of a wire winding device for welding wire production according to the present invention;

FIG. 8 is a schematic view of a first rotating block of an embodiment of a wire winding device for welding wire production according to the present invention;

Fig. 9 is a schematic structural view of a drum of an embodiment of a wire winding device for welding wire production according to the present invention.

Reference numerals illustrate:

110. a base; 120. i-shaped wheel; 130. a reel; 140. a first rotating shaft; 150. a second rotating shaft; 160. a first baffle; 170. a second baffle; 180. a stop block; 190. an electromagnet; 210. a first abutting plate; 220. a second abutting plate; 230. a slide; 240. a support base; 250. a first slide rail; 260. a first screw rod; 270. a second motor; 280. a rotating drum; 290. a first motor; 310. a first rotating block; 320. a second turntable; 330. a first support arm; 340. a first gear; 350. a second through hole; 360. a first outer ring gear; 370. a fixing plate; 380. a support block; 390. a U-shaped plate; 410. a support plate; 420. a first wall; 430. a second wall; 440. a third wall; 450. a rotating column; 460. a first turntable; 480. a limit column; 490. a first stop lever; 510. a second limit rod; 520. a first elongated slot; 530. a second elongated slot; 540. a first arc-shaped groove; 550. a second arc-shaped groove; 560. a limiting plate; 570. a connecting cylinder; 580. a groove; 590. a third bearing; 610. a circular groove; 620. a third through hole; 630. a first bearing; 640. a disc; 650. a first through hole; 660. a carrier plate; 670. a wedge-shaped extrusion block; 680. a fourth wall; 690. a fifth wall; 710. a sixth wall; 720. a second rotating block; 730. a spring; 740. a second screw rod; 750. a positioning rod; 760. a third motor; 770. a connecting seat; 780. a nut sleeve; 790. and a second outer ring gear.

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

Detailed Description

The following description of the embodiments of the present invention will be made clearly and fully with reference to the accompanying drawings, in which it is evident that the embodiments described are only some, but not all embodiments of the invention. All other embodiments, which can be made by those skilled in the art based on the embodiments of the invention without making any inventive effort, are intended to be within the scope of the invention.

It should be noted that all directional indicators (such as up, down, left, right, front, and rear … …) in the embodiments of the present invention are merely used to explain the relative positional relationship, movement, etc. between the components in a particular posture (as shown in the drawings), and if the particular posture is changed, the directional indicator is changed accordingly.

Furthermore, descriptions such as those referred to as "first," "second," and the like, are provided for descriptive purposes only and are not to be construed as indicating or implying a relative importance or implying an order of magnitude of the indicated technical features in the present disclosure. Thus, a feature defining "a first" or "a second" may explicitly or implicitly include at least one such feature. In the description of the present invention, the meaning of "plurality" means at least two, for example, two, three, etc., unless specifically defined otherwise.

In the present invention, unless specifically stated and limited otherwise, the terms "connected," "affixed," and the like are to be construed broadly, and for example, "affixed" may be a fixed connection, a removable connection, or an integral body; can be mechanically or electrically connected; either directly or indirectly, through intermediaries, or both, may be in communication with each other or in interaction with each other, unless expressly defined otherwise. The specific meaning of the above terms in the present invention can be understood by those of ordinary skill in the art according to the specific circumstances.

In addition, the technical solutions of the embodiments of the present invention may be combined with each other, but it is necessary to be based on the fact that those skilled in the art can implement the technical solutions, and when the technical solutions are contradictory or cannot be implemented, the combination of the technical solutions should be considered as not existing, and not falling within the scope of protection claimed by the present invention.

The invention provides a wire collecting device for welding wire production.

Referring to fig. 1 to 9, in an embodiment of a wire winding device for welding wire production according to the present invention, the wire winding device includes a base 110, a spool 120, a first rotating block 310, a disc 640, a sliding seat 230, a rotating drum 280 and a first motor 290; the base 110 is horizontally arranged; spool 120 includes a spool 130, a first shaft 140, and a second shaft 150; the first rotating shaft 140 and the second rotating shaft 150 are respectively and detachably arranged at two ends of the winding drum 130 (for example, the first rotating shaft 140 is in threaded connection with one end of the winding drum 130, and the second rotating shaft 150 is in threaded connection with the other end of the winding drum 130); the central axis of the drum 130, the central axis of the first shaft 140 and the central axis of the second shaft 150 are collinear; the first rotating block 310 is rotatably disposed on the upper surface of the base 110.

The first rotating block 310 is rotationally embedded with a disc 640; the disc 640 is provided with a first through hole 650 for inserting the first rotating shaft 140 therethrough; the rotation axis of the first rotating block 310 is perpendicular to the rotation axis of the disc 640, and the rotation axis of the first rotating block 310 is horizontally disposed; the sliding base 230 is horizontally slidably disposed on the upper surface of the base 110, and the sliding direction of the sliding base 230 is perpendicular to the rotation axis of the first rotating block 310; the rotary drum 280 is rotatably arranged on the sliding seat 230, and a second through hole 350 for embedding the second rotating shaft 150 is formed through the rotary drum 280; the first rotating block 310 can rotate until the central axis of the first through hole 650 is in a horizontal state; when the central axis of the first through hole 650 is in a horizontal state, the central axis of the first through hole 650 and the central axis of the second through hole 350 are collinear; the first motor 290 is disposed on the sliding base 230 for driving the rotating drum 280 to rotate.

In addition, spool 120 further includes a first baffle 160 and a second baffle 170; the first baffle 160 is disposed on a side of the drum 130 near the first rotation shaft 140, the second baffle 170 is disposed on a side of the drum 130 near the second rotation shaft 150, and the first baffle 160 is parallel to the second baffle 170.

The wire collecting device for welding wire production provided by the invention can more conveniently and rapidly discharge the welding wire after winding; specifically, before winding, the first rotating shaft 140 of the spool 120 is vertically embedded into the first through hole 650 (as shown in fig. 1), then the first rotating block 310 is rotated to enable the first rotating shaft 140 to be in a horizontal state, then the sliding seat 230 is slid to enable the sliding seat 230 to slide towards a direction close to the second rotating shaft 150, finally the second rotating shaft 150 is embedded into the second through hole 350 (as shown in fig. 2), then the first motor 290 is started to drive the rotating drum 280 to rotate, thereby driving the spool 120 to rotate, and further, wire winding is achieved, after winding is completed, the sliding seat 230 is slid again to enable the sliding seat 230 to move towards a direction far away from the second rotating shaft 150, finally the second rotating shaft 150 is pulled away from the second through hole 350, then the first rotating block 310 is rotated to enable the spool 120 to return to a vertical state, then the first rotating shaft 140 is pulled away from the first through hole 650, thus the whole spool 120 is dismounted, the blanking of welding wires can be directly completed, the step of dismounting the spool 130 from the spool 120 is omitted, and subsequently the spool 150 and the spool 150 can be directly dismounted from the spool 150 for packaging; the whole production process does not need to set additional installation equipment and installation personnel, so that the production cost is reduced, and the energy conservation and synergy in the production and manufacturing process are facilitated.

In addition, as shown in fig. 1, 2 and 4, the wire winding device for welding wire production further comprises a first supporting arm 330, a second supporting arm (not shown) and an electromagnet 190; the first support arm 330 and the second support arm are both disposed on the upper surface of the base 110; the first rotating block 310 is rotatably arranged between the first supporting arm 330 and the second supporting arm; the first abutting plate 210 is connected to the first rotating block 310; the electromagnet 190 is disposed on the upper surface of the base 110; the electromagnet 190 is used for attracting the first abutting plate 210; when the electromagnet 190 attracts the first abutting plate 210, the first abutting plate 210 is in a horizontal state, and the central axis of the first through hole 650 is vertically arranged.

Through setting up electro-magnet 190 and first butt plate 210, when electro-magnet 190 circular telegram and actuation first butt plate 210, can make first rotating block 310 include the vertical setting of axis of first through-hole 650, and then guarantee that first pivot 140 can be more smooth imbed in the first through-hole 650.

Meanwhile, the wire winding device for welding wire production further comprises a stop block 180 arranged on the upper surface of the base 110 and a second abutting plate 220 connected to the first rotating block 310; the second abutting plate 220 is parallel to the first abutting plate 210; when the electromagnet 190 attracts the first abutting plate 210, the second abutting plate 220 is located at one side of the first abutting plate 210 near the sliding seat 230; the stopper 180 is located between the first support arm 330 and the second support arm, and the stopper 180 includes a blocking wall (not numbered) disposed vertically, and the blocking wall faces the slider 230; the first rotating block 310 can rotate until the second abutting plate 220 abuts against the blocking wall; when the second abutting plate 220 abuts against the blocking wall, the second abutting plate 220 is vertically arranged, and the central axis of the first through hole 650 is horizontally arranged.

Specifically, by providing the second abutting plate 220, the position of the first rotating block 310 can be abutted, so that the first rotating block 310 is prevented from excessively rotating under the dead weight of the spool 120, that is, the first rotating block 310 can only rotate to the central axis of the first through hole 650 at most to be horizontal (at this time, the sliding seat 230 is slid again, so that the second rotating shaft 150 is embedded into the second through hole 350).

In addition, as shown in fig. 8 and 9, the first rotating block 310 is provided with a third through hole 620 therethrough; the third through hole 620 is embedded with a first bearing 630 (the first bearing 630 is a tapered roller bearing, so that when the spool 120 is vertically embedded into the first through hole 650, the first bearing 630 is more convenient to bear the dead weight of the whole spool 120); the disc 640 is embedded in the first bearing 630; the first through hole 650 is a circular hole, and the first rotating shaft 140 is a circular shaft embedded in cooperation with the first through hole 650; the upper surface of the sliding seat 230 is provided with a supporting seat 240; the support seat 240 is horizontally provided with a fourth through hole; a second bearing is embedded in the fourth through hole; the rotary drum 280 is embedded in the second bearing; the rotary drum 280 is coaxially sleeved with a first outer gear ring 360, and the first outer gear ring 360 is positioned on one side of the supporting seat 240 away from the rotary block; the output shaft of the first motor 290 is coaxially connected with a first gear 340; the first gear 340 meshes with a first outer ring gear 360; the second through hole 350 is a rectangular hole; the cross section of the end of the second rotating shaft 150 is rectangular and is embedded with the second through hole 350. Through the above-described technical solution, the related structures of the disc 640 and the drum 280 are completed.

Meanwhile, as shown in fig. 1, fig. 4, fig. 5 and fig. 6, the wire collecting device for welding wire production further comprises a limiting component; the limiting assembly comprises a U-shaped plate 390, a rotary column 450, a connecting cylinder 570, a third bearing 590 and a limiting plate 560; the first rotation block 310 includes a first wall 420 and a second wall 430 parallel to each other, and a third wall 440 between the first wall 420 and the second wall 430; the first abutting plate 210 is connected to the first wall 420; the second abutment plate 220 is connected to the second wall 430; the U-shaped plate 390 is connected to the third wall 440; the U-shaped board 390 includes a support plate 410 parallel to the first abutment plate 210.

The support plate 410 is provided with a first screw hole (not shown) therethrough; the first threaded hole and the first through hole 650 are coaxial; the outer wall of the rotary column 450 is provided with external threads which are matched with the first threaded hole in a screwing way; the rotary column 450 is rotatably arranged through the first threaded hole; one end of the rotary post 450 adjacent to the first through hole 650 is provided with a groove 580; the groove 580 is embedded with a third bearing 590; the connecting tube 570 is fitted in a third bearing 590 (the third shaft is also a tapered roller bearing); the limiting plate 560 is connected to one end of the connection cylinder 570 near the first through hole 650; the connection cylinder 570 and the first through hole 650 share a central axis; limiting plate 560 is perpendicular to the central axis of connecting cylinder 570; the limiting plate 560 is used to abut the end surface of the first shaft 140 away from the spool 130.

The limiting assembly is used for limiting the axial position of the first rotating shaft 140, firstly, when the first rotating shaft 140 is embedded into the first through hole 650, the limiting plate 560 can be abutted against the tail end of the first rotating shaft 140, and secondly, when the spool 120 rotates, the first rotating shaft 140 can be prevented from moving towards the direction close to the limiting plate 560.

Specifically, by twisting the rotation post 450, the distance between the limiting plate 560 and the first rotating block 310 can also be adjusted, so that the depth of the first rotating shaft 140 which can be inserted into the first through hole 650 is adjusted to be suitable for the first rotating shafts 140 with different lengths (the lengths of the first rotating shafts 140 of the spool 120 with different sizes are different).

Meanwhile, the limit assembly further comprises a limit post 480, a first limit lever 490, a second limit lever 510, a first rotary disc 460 and a second rotary disc 320; the stopper column 480 is connected to a side of the stopper plate 560 facing the first through hole 650; the limit column 480 and the connecting cylinder 570 share the central axis; the first limit lever 490 and the second limit lever 510 are respectively connected to two sides of the outer wall of the limit post 480; the central axis of the first limit lever 490 and the central axis of the second limit lever 510 are collinear; the end surface of the first rotating shaft 140 far away from the winding drum 130 is provided with a circular groove 610; the depth of the circular groove 610 is consistent with the length of the stopper column 480.

The central axis of the circular groove 610 and the central axis of the first rotation shaft 140 are collinear; the inner wall of the circular groove 610 is provided with a first long groove 520 and a second long groove 530 which are opposite to each other, a first arc-shaped groove 540 communicated with the first long groove 520, and a second arc-shaped groove 550 communicated with the second long groove 530; the distance between the first arc-shaped groove 540 and the end surface of the first rotation shaft 140, which is far from the winding drum 130, is identical to the distance between the second arc-shaped groove 550 and the end surface of the first rotation shaft 140, which is far from the winding drum 130; the distance between the first arc-shaped groove 540 and the end surface of the first rotating shaft 140 far from the winding drum 130 is consistent with the distance between the first limit lever 490 and the limit plate 560; the distance between the second arc-shaped groove 550 and the end surface of the first rotation shaft 140 far from the winding drum 130 is consistent with the distance between the second limit lever 510 and the limit plate 560; the first limit lever 490 is configured to be inserted into the first arcuate slot 540, and the second limit lever 510 is configured to be inserted into the second arcuate slot 550.

Specifically, after the first rotating shaft 140 is embedded into the first through hole 650, the limit post 480 is embedded into the circular groove 610 in a matching manner, and at this time, the limit plate 560 is abutted against the end surface of the first rotating shaft 140 far away from the winding drum 130, and then the connecting cylinder 570 is rotated, so that the first limit rod 490 is embedded into the first arc-shaped groove 540, and the second limit rod 510 is embedded into the second arc-shaped groove 550, so that the axial position of the first rotating shaft 140 relative to the connecting cylinder 570 is fixed, and therefore, the spool 120 is prevented from jumping in the axial position in the rotating process, and the work is more stable.

In addition, the first rotating disc 460 is sleeved on the connecting cylinder 570, and the first rotating disc 460 and the connecting cylinder 570 share the central axis; the second turntable 320 is sleeved on the rotating column 450, and the second turntable 320 and the rotating column 450 share the central axis; the second turntable 320 is located on a side of the support plate 410 facing away from the first turntable 310. By providing the first dial 460 to facilitate rotation of the connecting cylinder 570, by providing the second dial 320 to facilitate rotation of the rotary post 450.

Meanwhile, the wire collecting device for welding wire production further comprises a first sliding rail 250, a second sliding rail (not shown), a first screw 260, a connecting block (not shown) and a second motor 270; the first sliding rail 250 and the second sliding rail are both disposed on the upper surface of the base 110; the first rail 250 is parallel to the second rail; the sliding seat 230 is slidably connected to the first sliding rail 250 and the second sliding rail; the length direction of the first slide rail 250 is parallel to the central axis of the drum 280; the first screw 260 is rotatably disposed on the upper surface of the base 110; the connecting block is connected to the bottom of the slide 230; the first screw 260 is located between the first slide rail 250 and the second slide rail; the second motor 270 is disposed on the upper surface of the base 110, and is used for driving the first screw 260 to rotate; the first screw 260 is parallel to the first slide rail 250; the connecting block is provided with a second threaded hole (not shown) which is screwed with the screw rod in a matching way; the screw rod is matched and penetrated in the second threaded hole.

Through the above technical scheme, the technical scheme that the sliding base 230 is slidably connected to the base 110 is perfected, that is, the sliding base 230 is driven to slide horizontally on the base 110 by the second motor 270.

In addition, the wire collecting device for welding wire production further comprises a fixing assembly; the fixing assembly includes a second rotation block 720, a support block 380, a bearing plate 660, a fixing plate 370, a spring 730, a wedge-shaped extrusion block 670, and a driving part; the bearing plate 660 is disposed on the upper surface of the base 110, and the length direction of the bearing plate 660 is consistent with the moving direction of the sliding seat 230; the bearing plate 660 is arranged close to the sliding seat 230, and the bearing plate 660 is horizontally arranged; the supporting block 380 is arranged on the upper surface of the carrier plate 660; the second rotating block 720 is rotatably arranged on the supporting block 380; the rotation axis of the second rotation block 720 is parallel to the length direction of the carrier plate 660, and the rotation axis of the second rotation block 720 is horizontally arranged; the fixing plate 370 is connected to the second rotating block 720; the length direction of the fixing plate 370 is parallel to the length direction of the carrier plate 660.

The fixing plate 370 is located at a side of the second rotation block 720 remote from the carrier plate 660; one end of the spring 730 is connected to the second rotation block 720, and the other end of the spring 730 is connected to the carrier plate 660; the spring 730 is in a stretched state, so that the second rotating block 720 has a tendency to drive the fixed plate 370 to rotate away from the sliding seat 230; the wedge-shaped extrusion block 670 is slidably embedded between the bearing plate 660 and the second rotating block 720; the driving component is used for driving the wedge-shaped extrusion block 670 to horizontally move; the wedge-shaped extrusion block 670 is used for surface contact and abutting against the second rotation block 720 so as to keep the fixing plate 370 horizontal; when the fixing plate 370 is kept horizontal, the fixing plate 370 abuts against the upper surface of the slider 230, and the upper surface of the slider 230 is disposed horizontally.

The position of the sliding seat 230 can be fixed by arranging the fixing component, so that the sliding seat 230 is prevented from shaking when the spool 120 rotates during working; specifically, in a normal state, the wedge-shaped extrusion block 670 does not completely abut (i.e., does not face contact) the second rotation block 720, and the second rotation block 720 rotates under the action of the spring 730 until the fixing plate 370 is separated from the upper surface of the slide 230; when the slide 230 moves to a proper position, the driving component is started, and the driving component drives the wedge extrusion block 670 to translate towards the direction approaching to the slide 230, so that the wedge extrusion block 670 is completely abutted between the second rotating block 720 and the bearing plate 660 (i.e. the wedge extrusion block 660 contacts with the lower side surface of the second rotating block 720), in this process, the second rotating block 720 is forced to rotate, and the rotation direction is that the fixing plate 370 rotates towards the direction approaching to the slide 230, finally, the fixing plate 370 rotates to a horizontal state, and at this time, the fixing plate 370 is completely abutted against the upper surface of the slide 230 (as shown in fig. 7), so as to fix the position of the slide 230.

Meanwhile, the wedge-shaped extrusion block 670 includes a fourth wall 680 disposed horizontally, and a fifth wall 690 disposed obliquely; the side of the fifth wall 690 remote from the sled 230 is higher than the side proximate to the sled 230; the second swivel block 720 includes a sixth wall 710 for conforming contact with the fifth wall 690. Through the above technical scheme, the structures of the wedge-shaped extrusion block 660 and the second rotation block 720 are perfected.

The driving part includes a second screw 740, a nut housing 780, a connection block 770, a second external gear ring 790, a third motor 760 and a positioning rod 750; the second screw 740 is horizontally connected with one end of the wedge-shaped extrusion block 670, which is far away from the sliding seat 230; the second screw 740 is provided with a through groove (not shown); the cross section of the through groove is rectangular; the positioning rod 750 is horizontally and fixedly connected to the upper surface of the base 110, and the cross section of the positioning rod 750 is rectangular; the positioning rod 750 is matched with the sliding embedded groove; the central axis of the second screw 740 is perpendicular to the sliding direction of the slider 230.

The nut sleeve 780 is matched and sleeved on the second screw rod 740; the outer wall of the nut sleeve 780 is fixedly sleeved with a second outer gear ring 790; the connection seat 770 is connected to the upper surface of the base 110, and a fourth bearing (not shown) is rotatably embedded in the connection seat 770; the nut sleeve 780 is fixedly embedded in the inner ring of the fourth bearing, and the second screw 740 and the fourth bearing share the central axis; the second outer gear ring 790 and the second screw 740 share a central axis; the third motor 760 is disposed on the upper surface of the base 110, and is used for driving the second external gear ring 790 to rotate, so as to drive the second screw 740 to move horizontally, and to drive the wedge-shaped extrusion block 670 to move horizontally.

Through the above technical scheme, the structure of the fixing assembly is perfected, the structure and the function of the driving component are improved, when the wedge 660 needs to be driven to translate, the third motor 760 is started to drive the nut sleeve 780 to rotate, the second screw 740 is matched with the threaded sleeve 780, the second screw 740 cannot rotate under the action of the positioning rod 750, and the rotating nut sleeve 780 can drive the second screw 740 to horizontally move, so that the wedge 660 is driven to translate.

The foregoing description is only of the preferred embodiments of the present invention and is not intended to limit the scope of the invention, and all equivalent structural changes made by the description of the present invention and the accompanying drawings or direct/indirect application in other related technical fields are included in the scope of the invention.

Claims

1. The wire collecting device for welding wire production is characterized by comprising a base, a spool, a first rotating block, a disc, a sliding seat, a rotating drum and a first motor; the base is horizontally arranged; the spool comprises a winding drum, a first rotating shaft and a second rotating shaft; the first rotating shaft and the second rotating shaft are respectively detachably arranged at two ends of the winding drum; the central axis of the winding drum, the central axis of the first rotating shaft and the central axis of the second rotating shaft are collinear; the first rotating block is rotatably arranged on the upper surface of the base;

the disc is rotationally embedded in the first rotating block; the disc is provided with a first through hole in a penetrating way, and the first through hole is used for being embedded into the first rotating shaft; the rotating shaft of the first rotating block is perpendicular to the rotating shaft of the disc, and the rotating shaft of the first rotating block is horizontally arranged; the sliding seat is horizontally arranged on the upper surface of the base in a sliding manner, and the sliding direction of the sliding seat is perpendicular to the rotating shaft of the first rotating block; the rotary drum is rotatably arranged on the sliding seat, and a second through hole for being embedded into the second rotating shaft is formed in the rotary drum in a penetrating manner; the first rotating block can rotate until the central axis of the first through hole is in a horizontal state; when the central axis of the first through hole is in a horizontal state, the central axis of the first through hole and the central axis of the second through hole are collinear; the first motor is arranged on the sliding seat and used for driving the rotary drum to rotate;

The device also comprises a first supporting arm, a second supporting arm and an electromagnet; the first support arm and the second support arm are both arranged on the upper surface of the base; the first rotating block is rotatably arranged between the first supporting arm and the second supporting arm; the first rotating block is connected with a first abutting plate; the electromagnet is arranged on the upper surface of the base; the electromagnet is used for attracting the first abutting plate; when the electromagnet attracts the first abutting plate, the first abutting plate is in a horizontal state, and the central axis of the first through hole is vertically arranged;

the device also comprises a stop block arranged on the upper surface of the base and a second abutting plate connected with the first rotating block; the second abutting plate is parallel to the first abutting plate; when the electromagnet attracts the first abutting plate, the second abutting plate is positioned on one side of the first abutting plate, which is close to the sliding seat; the stop block is positioned between the first support arm and the second support arm, the stop block comprises a stop wall which is vertically arranged, and the stop wall faces the sliding seat; the first rotating block can rotate until the second abutting plate abuts against the blocking wall; when the second abutting plate abuts against the blocking wall, the second abutting plate is vertically arranged, and the central axis of the first through hole is horizontally arranged;

The device also comprises a limiting component; the limiting assembly comprises a U-shaped plate, a rotating column, a connecting cylinder, a third bearing and a limiting plate; the first swivel block includes a first wall and a second wall parallel to each other, and a third wall between the first wall and the second wall; the first abutting plate is connected to the first wall; the second abutting plate is connected to the second wall; the U-shaped plate is connected to the third wall; the U-shaped plate comprises a support plate parallel to the first abutting plate;

the supporting plate is provided with a first threaded hole in a penetrating mode; the first threaded hole and the first through hole share a central axis; the outer wall of the rotary column is provided with external threads which are matched with the first threaded hole in a screwing mode; the rotary column is rotatably arranged through the first threaded hole; a groove is formed in one end, close to the first through hole, of the rotary column; the groove is embedded with the third bearing; the connecting cylinder is embedded in the third bearing; the limiting plate is connected to one end, close to the first through hole, of the connecting cylinder; the connecting cylinder and the first through hole share a central axis; the limiting plate is perpendicular to the central axis of the connecting cylinder; the limiting plate is used for abutting against the end face, far away from the winding drum, of the first rotating shaft;

The limiting assembly further comprises a limiting column, a first limiting rod and a second limiting rod; the limiting column is connected to one side, facing the first through hole, of the limiting plate; the limiting column and the connecting cylinder share the central axis; the first limiting rod and the second limiting rod are respectively connected to two sides of the outer wall of the limiting column; the central axis of the first limiting rod and the central axis of the second limiting rod are collinear; the end face, far away from the winding drum, of the first rotating shaft is provided with a circular groove; the depth of the circular groove is consistent with the length of the limit column;

2. The wire winding device for producing welding wire according to claim 1, wherein the first rotating block is provided with a third through hole; the third through hole is embedded with a first bearing; the disc is embedded in the first bearing; the first through hole is a circular hole, and the first rotating shaft is a circular shaft which is embedded with the first through hole in a matching way; the upper surface of the sliding seat is provided with a supporting seat; the support seat is horizontally provided with a fourth through hole in a penetrating way; a second bearing is embedded in the fourth through hole; the rotary drum is embedded in the second bearing; the rotary drum is coaxially sleeved with a first outer gear ring; an output shaft of the first motor is coaxially connected with a first gear; the first gear is meshed with the first outer gear ring; the second through hole is a rectangular hole; the cross section of the tail end of the second rotating shaft is rectangular and embedded with the second through hole in a matching mode.

3. The wire take-up device for welding wire production of claim 1, further comprising a first slide rail, a second slide rail, a first screw, a connecting block, and a second motor; the first sliding rail and the second sliding rail are arranged on the upper surface of the base; the first sliding rail is parallel to the second sliding rail; the sliding seat is connected with the first sliding rail and the second sliding rail in a sliding manner; the length direction of the first sliding rail is parallel to the central axis of the rotary drum; the first screw rod is rotatably arranged on the upper surface of the base; the connecting block is connected to the bottom of the sliding seat; the first screw rod is positioned between the first sliding rail and the second sliding rail; the second motor is arranged on the upper surface of the base and used for driving the first screw rod to rotate; the first screw rod is parallel to the first sliding rail; the connecting block is provided with a second threaded hole which is screwed with the screw rod in a matched manner; the screw rod is matched with and penetrates through the second threaded hole.

4. The wire take-up device for welding wire production of claim 1, further comprising a securing assembly; the fixing assembly comprises a second rotating block, a supporting block, a bearing plate, a fixing plate, a spring, a wedge-shaped extrusion block and a driving part; the bearing plate is arranged on the upper surface of the base, and the length direction of the bearing plate is consistent with the moving direction of the sliding seat; the bearing plate is arranged close to the sliding seat; the supporting block is arranged on the upper surface of the bearing plate; the second rotating block is rotatably arranged on the supporting block; the rotating shaft of the second rotating block is parallel to the length direction of the bearing plate; the fixed plate is connected to the second rotating block; the length direction of the fixing plate is parallel to the length direction of the bearing plate;

5. The wire takeup device for welding wire production of claim 4 wherein said wedge shaped extrusion block includes a fourth wall disposed horizontally and a fifth wall disposed obliquely; the side of the fifth wall, which is far away from the sliding seat, is higher than the side, which is close to the sliding seat; the second rotating block comprises a sixth wall for abutting contact with the fifth wall;

6. The wire take-up device for welding wire production of claim 1, wherein the spool further comprises a first baffle and a second baffle; the first baffle plate is arranged on one side of the winding drum, which is close to the first rotating shaft, the second baffle plate is arranged on one side of the winding drum, which is close to the second rotating shaft, and the first baffle plate is parallel to the second baffle plate.