CN108889885B

CN108889885B - Copper wire forming device

Info

Publication number: CN108889885B
Application number: CN201810842037.7A
Authority: CN
Inventors: 章日平; 廖旺生
Original assignee: Juli Automation Equipment Zhejiang Co Ltd
Current assignee: Juli Automation Equipment Zhejiang Co Ltd
Priority date: 2018-07-27
Filing date: 2018-07-27
Publication date: 2023-11-17
Anticipated expiration: 2038-07-27
Also published as: CN108889885A

Abstract

The invention discloses a copper wire forming device which comprises a forming power mechanism, a forming extrusion mechanism connected to the forming power mechanism and a forming wire feeding mechanism arranged on the forming extrusion mechanism. According to the invention, the annular array on the wire feeding disc is provided with the conveying grooves, so that copper wires can be continuously conveyed, and the copper wire adding efficiency is improved; the power disc is provided with a power column in a centrifugal way on one side, and a swing arm is arranged on the other side in a sliding way in the slot cam to provide power sources for the rotation of the power disc, so that the power disc has the output of two power sources in the rotation process and is positioned on the same power rotating shaft, and errors can not be generated after long-time operation; the extrusion plate II moves up and down through the push-pull arm I and the corresponding sliding component, extrusion of the copper wire in the longitudinal direction is completed, the copper wire is transversely extruded through the forward and backward movement of the push-pull arm II and the transverse punching die, extrusion of the copper wire in the transverse direction is completed, and the copper wire extrusion device is complete in overall function and high in practicability.

Description

Copper wire forming device

Technical Field

The invention relates to the technical field of copper wire forming, in particular to a copper wire forming device.

Background

The copper wire is unreeled from the winding on the copper wire winding shaft, and is manufactured into a corresponding shape through subsequent cutting and extrusion molding. In the copper wire forming process, the copper wire needs to be extruded in different directions, if the copper wire needs to be extruded in two directions, two groups of power sources are needed, so that the whole structure of the equipment is large, and even if the two groups of power sources are operated at the same time, larger errors can be generated for a long time, and the forming effect of the product is influenced; and in the extrusion molding process, the unshaped copper wire is required to be extruded into a corresponding shape through a die, but the existing mechanism does not relate to the operation of molding one copper wire in two directions, the unshaped copper wire is placed at the position of the extrusion die one by one, the reciprocating conveying speed is also slower, the molding speed is influenced, the productivity of equipment is reduced, and the overall effect is poor. Accordingly, the invention provides a copper wire forming device.

Disclosure of Invention

The invention aims to overcome the defects in the prior art, and provides a copper wire forming device which is provided with a single-end power source input, a double-end power source output, and a disc type wire feeding mechanism, wherein the double-end power source respectively performs extrusion forming on copper wires in the longitudinal direction and the transverse direction at the same time, so that more complex extrusion forming operation is completed, the mechanism can enable the un-formed copper wires to be continuously conveyed to a forming extrusion mechanism, the adding speed is high, and the working efficiency is improved.

In order to solve the technical problems, the aim of the invention is realized as follows: the invention relates to a copper wire forming device which comprises a forming power mechanism, a forming extrusion mechanism connected to the forming power mechanism and a forming wire feeding mechanism arranged on the forming extrusion mechanism;

the forming power mechanism comprises a mechanism platen, a speed reducer is fixedly arranged on the mechanism platen, the speed reducer is provided with an input end and an output end, a motor III is connected to the input end, a power rotating shaft is arranged on the output end, a power disc which rotates together with the power rotating shaft is sleeved on the power rotating shaft, a power column is arranged on the edge of one end face of the power disc, a joint bearing is sleeved on the power column, a swing arm is arranged on the other end face side of the power disc, a roller is arranged on the swing arm, a grooved cam is arranged on the end face, located on the swing arm side, of the power disc, and the roller is connected to the grooved cam in a sliding mode; the lower end of the swing arm penetrates through the swing arm through hole and is hinged to the bearing with the seat;

the forming extrusion mechanism comprises an extrusion platform, wherein side frames are arranged on two sides of the extrusion platform, a rear frame is arranged between the side frames, a side vertical rail is vertically arranged on the side frames, a side sliding block is connected to the side vertical rail in a sliding manner, a side guide block is fixedly connected to the side sliding block, a side guide groove is formed in the side guide block, an extrusion plate I is connected to the side sliding manner, an extrusion plate II is connected to the lower side of the extrusion plate in a sliding manner, a rear sliding block is fixedly connected to the rear end of the extrusion plate II, the rear sliding block is connected to the rear vertical rail vertically arranged on the rear frame in a sliding manner, an extrusion arm I is hinged to the extrusion plate I, an extrusion arm II is arranged on the extrusion arm I, the upper end of the extrusion arm II is hinged to the side frame, a push-pull arm I is also hinged to the upper end of the extrusion arm II, a cutter head fixing block is arranged below the side of the side sliding block, a V-shaped pressing piece is arranged on the cutter head fixing block, a push-pull forming die is also arranged on the rear frame, a front die is arranged on the side surface of the extrusion block, a V-shaped groove is formed on the side surface of the extrusion die is arranged on the side surface of the extrusion plate, and is in a horizontal direction fit with a horizontal die groove, and a front die is hinged to the front die groove is formed on the side of the die;

the forming wire feeding mechanism comprises a quick-change shaft which is transversely connected to the side frame in a rotating mode, wire feeding disks are arranged on two sides of the quick-change shaft, a synchronous pulley five is further arranged at one end portion of the quick-change shaft, a synchronous pulley six is arranged on a vertical face of the synchronous pulley five, a motor four is connected to the synchronous pulley six, the synchronous pulley five is connected with the synchronous pulley six through a synchronous belt three-transmission mode, a plurality of conveying grooves are formed in the periphery of the wire feeding disks in an annular array mode and comprise an input conveying groove and an output conveying groove, a stop block which is wrapped on the side wall face of the wire feeding disks is arranged between the input conveying groove and the output conveying groove, and the stop block is fixedly connected with the side frame.

The invention is further provided with: the mechanism platen is also provided with a fixed seat, the fixed seat is provided with a cam guide device, and the cam guide device is abutted on the side wall surface of the power disc and rotates together with the power disc.

The invention is further provided with: eight conveying grooves are arranged on the periphery of the wire feeding disc in an annular array with equal interval angles, and the notch orientation of two adjacent conveying grooves is 45 degrees.

In summary, the invention has the following beneficial effects: according to the copper wire forming device, the annular arrays on the wire feeding disc are provided with the conveying grooves, so that copper wires can be continuously conveyed, the copper wire adding efficiency is improved, and the forming speed is improved; the power disc is provided with a power column in a centrifugal way on one side of the power disc, and a swing arm is arranged on the other side of the power disc in a sliding way by the groove cam to provide power sources for the rotation of the power disc, so that the power disc has the output of two power sources in the rotation process and is positioned on the same power rotating shaft, errors can not be generated after long-time operation, and the product forming effect is good; through push-pull arm and corresponding slip subassembly, realize the reciprocates of stripper plate two to drive V-arrangement preforming up-and-down motion, accomplish the extrusion of copper line in longitudinal direction, and through the back-and-forth movement of push-pull arm two and horizontal die, transversely extrude the copper line, accomplish the extrusion of copper line in horizontal direction, make extrusion mechanism have can carry out extrusion's function simultaneously to the copper line from vertical and horizontal two directions, whole function is perfect, and the practicality is strong.

Drawings

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

FIG. 2 is a schematic view of the configuration of the molded power mechanism of the present invention;

FIG. 3 is a schematic diagram of a swing arm and slot cam configuration embodying the present invention;

FIG. 4 is a schematic view of the structure of the molding press of the present invention;

FIG. 5 is a schematic view of a portion of the structure of the forming press mechanism of the present invention;

FIG. 6 is a schematic view of the structure of a V-shaped tablet;

FIG. 7 is a schematic view of the structure of an extruded block;

FIG. 8 is a schematic view of the structure of the transverse die;

FIG. 9 is a schematic view of the forming wire feeding mechanism of the present invention;

fig. 10 is a schematic view of the structure of the wire feeding disc;

reference numerals illustrate: 6000. forming a power mechanism; 7000. forming and extruding mechanisms; 8000. a molding wire feeding mechanism; 150. a mechanism platen; 151. a speed reducer; 152. an input end; 153. an output end; 154. a third motor; 155. a power rotating shaft; 156. a power disc; 157. a power column; 158. a knuckle bearing; 159. swing arms; 160. a roller; 161. a slot cam; 162. the swing arm passes through the perforation; 163. a bearing with a seat; 164. a fixing seat; 165. a cam guide; 168. a side frame; 169. a quick-change shaft; 170. a wire feeding disc; 171. a synchronous pulley V; 172. a synchronous pulley six; 173. a fourth motor; 174. a synchronous belt III; 175. a transport tank; 176. inputting into a conveying groove; 177. outputting a conveying groove; 178. a stop block; 186. an extrusion platform; 187. a rear frame; 188. a side vertical rail; 189. a side slider; 190. a side guide block; 191. a side guide groove; 192. a first extrusion plate; 193. a second extrusion plate; 194. a rear slider; 195. a rear vertical rail; 196. the first extrusion arm is arranged; 197. a second extrusion arm; 198. push-pull arm I; 199. a cutter head fixing block; 200. v-shaped tabletting; 201. extruding and molding the block; 202. a V-shaped groove; 203. a transverse punching die; 204. push-pull arm II.

Detailed Description

The invention will be further described with reference to the drawings and preferred embodiments.

Referring to fig. 1, a copper wire forming apparatus according to the present embodiment includes a forming power mechanism 6000, a forming extrusion mechanism 7000 connected to the forming power mechanism 6000, and a forming wire feeding mechanism 8000 provided to the forming extrusion mechanism 7000; the molding extrusion mechanism 7000 has a longitudinal extrusion end, on which a first push-pull arm 198 is connected, and a transverse extrusion end, on which a second push-pull arm 204 is connected, and the molding power mechanism 6000 has two power source output ends, one being the power source output end of the upper end of the swing arm 159, which provides power to the first push-pull arm 198, and the other being the power column 157, which provides power to the second push-pull arm 204, and the molding wire feeding mechanism 8000 continuously conveys copper wires to be extrusion molded one by one to the molding extrusion mechanism 7000.

Referring to fig. 2-3, a copper wire forming device according to this embodiment includes a forming power mechanism 6000, wherein the forming power mechanism 6000 includes a mechanism platen 150, a speed reducer 151 is fixedly arranged on the mechanism platen 150, the speed reducer 151 has an input end 152 and an output end 153, a motor three 154 is connected to the input end 152, a power rotating shaft 155 is arranged on the output end 153, a power disc 156 which rotates together with the power rotating shaft 155 is sleeved on the power rotating shaft 155, a power column 157 is arranged on one end surface edge of the power disc 156, a joint bearing 158 is sleeved on the power column 157, a swing arm 159 is arranged on the other end surface side of the power disc 156, a roller 160 is arranged on the swing arm 159, a slot cam 161 is arranged on the end surface of the power disc 156 located on the swing arm 159, and the roller 160 is slidably connected with the slot cam 161; the mechanism bedplate 150 is also provided with a swing arm through hole 162, a seat bearing 163 fixedly connected to the lower end surface of the mechanism bedplate 150 is arranged below the swing arm through hole 162, and the lower end of the swing arm 159 passes through the swing arm through hole 162 and is hinged to the seat bearing 163;

further, the mechanism platen 150 is further provided with a fixing seat 164, the fixing seat 164 is provided with a cam guide 165, the cam guide 165 is abutted against a side wall surface of the power disc 156 and rotates together with the power disc 156, and because the upper end of the swing arm 159 and the joint bearing 158 are both power source output ends in the rotation process of the power disc 156, the center of the power disc 156 is easy to deviate from the axis of the power rotating shaft 155 in the thrust or tension applying process, the operation of the equipment is affected, and the cam guide 165 is additionally provided, so that the auxiliary guide function is realized, and the function of preventing the center of the power disc 156 from deviating from the axis of the power rotating shaft 155 is also realized.

In the mechanism, the motor III 154 is electrified and operated, the motor III 154 is driven by the speed reducer 151, the power rotating shaft 155 rotates, the power carrying disc 156 rotates together to drive the power column 157 to rotate around the center of the power disc 156, the joint bearing 158 is used for connecting the push-pull arm, namely the first power source output end, the slot cam 161 also rotates together in the rotating process of the power disc 156, the roller 160 is embedded and slides in the slot cam 161, the roller 160 is arranged on the swing arm 159, the swing arm 159 swings back and forth, the lower end of the swing arm 159 is hinged on the belt seat bearing 163, the rotation of the fulcrum at the lower end of the swing arm 159 is facilitated, the upper end of the swing arm 159 is also used for connecting the push-pull arm, namely the second power source output end, and the functions of single-ended power source input and double-ended power source output are realized.

Referring to fig. 1-8, a copper wire forming device according to this embodiment includes a forming extrusion mechanism 7000, wherein the forming extrusion mechanism 7000 includes an extrusion platform 186, side frames 168 are disposed on two sides of the extrusion platform 186, a rear frame 187 is disposed between the side frames 168, a side vertical rail 188 is vertically disposed on the side frames 168, a side sliding block 189 is slidably connected to the side vertical rail 188, a side guide block 190 is fixedly connected to the side sliding block 189, a side guide groove 191 is disposed on the side guide block 190, a first extrusion plate 192 is slidably connected to the side guide groove 191, a second extrusion plate 193 is slidably connected to the lower portion of the first extrusion plate 192, a rear slider 194 is fixedly connected to the rear end of the second extrusion plate 193, a rear vertical rail 195 is slidably connected to the rear frame 187, a first extrusion arm 196 is hinged to the first extrusion plate 192, a second extrusion arm 197 is disposed on the first extrusion arm 196, the upper end of the extrusion arm II 197 is hinged with the side frame 168, the lower end of the extrusion arm II 197 is hinged with the extrusion arm I196, the joint of the extrusion arm I196 and the extrusion arm II 197 is also hinged with a push-pull arm I198, the push-pull arm I198 is also hinged with the upper end of the swing arm 159, a tool bit fixing block 199 is arranged below the extrusion plate II 193, a V-shaped tabletting 200 is arranged on the tool bit fixing block 199, an extrusion forming block 201 positioned below the tool bit fixing block 199 is also arranged on the rear frame 187, a V-shaped groove 202 is formed on the front side of the extrusion forming block 201, a transverse punching die 203 which is in sliding connection with the extrusion platform 186 is arranged on the front side of the V-shaped groove 202, a push-pull arm II 204 is arranged on the transverse punching die 203, the push-pull arm II 204 is hinged with the power column 157, and the die head of the transverse punching die 203 is matched with the V-shaped groove 202;

in the mechanism, firstly, an unshaped copper wire (in a straight line) is placed on a punch of a transverse punch 203, a push-pull arm II 204 is pushed, the transverse punch 203 moves towards the side of an extrusion molding block 201, the copper wire is pushed into a V-shaped groove 202 of the extrusion molding block 201 to form a shape similar to the front half part of the transverse punch 203, then a push-pull arm I198 is pushed, the front end of the push-pull arm I198 moves between the extrusion arm I196 and the extrusion arm II 197, the extrusion arm I196 is forced to move downwards due to the hinging of the upper end of the extrusion arm II 197 and a side stand 168, the extrusion plate II 193 moves downwards with the extrusion plate I192 and the extrusion plate II 193, the extrusion plate II 193 slides on a rear vertical rail 195 through a rear sliding block 194, and the extrusion plate I192 slides in a side guide groove 191 of a side guide block 190 and slides on a side vertical rail 188 to finish the downward movement of a cutter head fixing block 199, and the V-shaped pressed piece 200 on the fixing block 199 is extruded from top to bottom after the copper wire is extruded transversely, so that both copper wires and the copper wire are extruded transversely and transversely simultaneously; the power source for pushing the second push-pull arm 204 is from the first power source output end (i.e. the joint bearing 158), and the power source for pushing the first push-pull arm 198 is from the second power source output end (i.e. the upper end of the swing arm 159).

Referring to fig. 9-10, in the copper wire forming device according to this embodiment, a forming wire feeding mechanism 8000 includes a quick-change shaft 169 rotatably connected to the side frame 168 in a transverse direction, wire feeding disks 170 are disposed on two sides of the quick-change shaft 169, a synchronous pulley five 171 is further disposed at one end of the quick-change shaft 169, a synchronous pulley six 172 is disposed on a vertical plane of the synchronous pulley five 171, a motor four 173 is connected to the synchronous pulley six 172, the synchronous pulley five 171 and the synchronous pulley six 172 are in transmission connection through a synchronous belt three 174, a plurality of conveying grooves 175 are formed in an annular array on a periphery of the wire feeding disks 170, the conveying grooves 175 include an input conveying groove 176 and an output conveying groove 177, a stop block 178 coated on a side wall surface of the wire feeding disks 170 is disposed between the input conveying groove 176 and the output conveying groove 177, and the stop block 178 is fixedly connected with the side frame 168;

further, eight conveying slots 175 are provided, and the slots of two adjacent conveying slots 175 are oriented at 45 degrees on the circumference of the wire feeding disc 170 in an equally-spaced angular annular array.

In this mechanism, by placing the unshaped copper wire (in a straight line) one by one into the input conveying groove 176 of the wire feeding disc 170 (that is, both ends of the unshaped copper wire are respectively arranged in the input conveying groove 176 of the wire feeding disc 170 at both ends of the quick-change shaft 169), at this time, the motor four 173 is in an operation state, the wire feeding disc 170 is rotated to the stopper 178 side by the third timing belt 174, the copper wire in the input conveying groove 176 is sent to the output conveying groove 177 by rotation and falls out from the output conveying groove 177, and the copper wire in the conveying groove 175 between the input conveying groove 176 and the output conveying groove 177 is prevented from falling out in the next process step (i.e., the punch front end of the unshaped copper wire falls to the transverse punch 203).

Referring to fig. 1 to 10, a copper wire forming apparatus according to the present embodiment transfers an unshaped copper wire from an input carrying tank 176 to an output carrying tank 177, and then drops from the output carrying tank 177 to a punch of a transverse die 203, the transverse die 203 pushes the copper wire through a power column 157 on a power disc 156, so that the transverse die 203 extrudes the copper wire onto an extrusion block 201, and a transverse extrusion operation is completed; then the swing arm 159 on the forming power mechanism 6000 moves to give power to the push-pull arm 198, the V-shaped pressing sheet 200 moves downwards through the corresponding transmission mechanism, the copper wire after one-step forming is extruded from top to bottom, and the longitudinal extrusion forming operation is completed, so that the cycle is completed.

According to the invention, the annular array on the wire feeding disc is provided with the conveying grooves, so that copper wires can be continuously conveyed, the copper wire adding efficiency is improved, and the forming speed is improved; the power disc is provided with a power column in a centrifugal way on one side of the power disc, and a swing arm is arranged on the other side of the power disc in a sliding way by the groove cam to provide power sources for the rotation of the power disc, so that the power disc has the output of two power sources in the rotation process and is positioned on the same power rotating shaft, errors can not be generated after long-time operation, and the product forming effect is good; through push-pull arm and corresponding slip subassembly, realize the reciprocates of stripper plate two to drive V-arrangement preforming up-and-down motion, accomplish the extrusion of copper line in longitudinal direction, and through the back-and-forth movement of push-pull arm two and horizontal die, transversely extrude the copper line, accomplish the extrusion of copper line in horizontal direction, make extrusion mechanism have can carry out extrusion's function simultaneously to the copper line from vertical and horizontal two directions, whole function is perfect, and the practicality is strong.

The foregoing describes in detail preferred embodiments of the present invention. It should be understood that numerous modifications and variations can be made in accordance with the concepts of the invention by one of ordinary skill in the art without undue burden. Therefore, all technical solutions which can be obtained by logic analysis, reasoning or limited experiments based on the prior art by the person skilled in the art according to the inventive concept shall be within the scope of protection defined by the claims.

Claims

1. Copper line forming device, its characterized in that: comprises a molding power mechanism (6000), a molding extrusion mechanism (7000) connected to the molding power mechanism (6000) and a molding wire feeding mechanism (8000) arranged on the molding extrusion mechanism (7000);

the forming power mechanism (6000) comprises a mechanism platen (150), a speed reducer (151) is fixedly arranged on the mechanism platen (150), the speed reducer (151) is provided with an input end (152) and an output end (153), a motor III (154) is connected to the input end (152), a power rotating shaft (155) is arranged on the output end (153), a power disc (156) which rotates along with the power rotating shaft (155) is sleeved on the power rotating shaft (155), a power column (157) is arranged on one end face edge of the power disc (156), a joint bearing (158) is sleeved on the power column (157), a swing arm (159) is arranged on the other end face side of the power disc (156), a roller (160) is arranged on the swing arm (159), and a groove cam (161) is arranged on the end face of the power disc (156) on the swing arm (159), and the roller (160) is connected to the groove cam (161) in a sliding mode; a swing arm through hole (162) is further formed in the mechanism bedplate (150), a seat bearing (163) fixedly connected to the lower end surface of the mechanism bedplate (150) is arranged below the swing arm through hole (162), and the lower end of the swing arm (159) penetrates through the swing arm through hole (162) and is hinged to the seat bearing (163);

the molding extrusion mechanism (7000) comprises an extrusion platform (186), side frames (168) are arranged on two sides of the extrusion platform (186), a rear frame (187) is arranged between the side frames (168), a side vertical rail (188) is vertically arranged on the side frames (168), a side sliding block (189) is connected to the side vertical rail (188) in a sliding manner, a side guide block (190) is fixedly connected to the side sliding block (189), a side guide groove (191) is formed in the side guide block (190), an extrusion plate I (192) is connected to the lower portion of the extrusion plate I (192) in a sliding manner, an extrusion plate II (193) is connected to the rear end of the extrusion plate II (193) in a sliding manner, a rear vertical rail (195) is arranged on the rear frame (187) in a sliding manner, an extrusion arm I (196) is hinged to the extrusion plate I (192), an extrusion arm II (197) is arranged on the extrusion arm I (196) in a fixedly connected manner, the upper end of the extrusion arm II (197) is hinged to the side frame (168), a push-pull arm II (196) is hinged to the extrusion arm I (196), a push-pull arm II (196) is connected to the extrusion arm II (196) in a hinged manner, and a push-pull arm II (198) is connected to the push-pull arm II (196) in a hinged manner, the cutter head fixing block (199) is provided with a V-shaped pressing sheet (200), the rear frame (187) is also provided with an extrusion molding block (201) positioned below the cutter head fixing block (199), the front side surface of the extrusion molding block (201) is provided with a V-shaped groove (202), the front side of the V-shaped groove (202) is provided with a transverse punching die (203) which is connected with the extrusion platform (186) in a sliding way, the transverse punching die (203) is provided with a push-pull arm II (204), the push-pull arm II (204) is hinged with the power column (157), and the die head of the transverse punching die (203) is matched with the V-shaped groove (202);

the forming wire feeding mechanism (8000) comprises a quick-change shaft (169) which is transversely and rotatably connected to the side frame (168), wire feeding disks (170) are arranged on two sides of the quick-change shaft (169), a synchronous pulley five (171) is further arranged at one end of the quick-change shaft (169), a synchronous pulley six (172) is arranged on a vertical surface of the synchronous pulley five (171), a motor four (173) is connected to the synchronous pulley six (172), the synchronous pulley five (171) and the synchronous pulley six (172) are in transmission connection through a synchronous belt three (174), a plurality of conveying grooves (175) are annularly arranged on the periphery of the wire feeding disks (170), the conveying grooves (175) comprise an input conveying groove (176) and an output conveying groove (177), a stop block (178) which is coated on the side wall surface of the wire feeding disks (170) is arranged between the input conveying grooves (176) and the output conveying grooves (177), and the stop block (178) is fixedly connected with the side frame (168).

A fixed seat (164) is further arranged on the mechanism bedplate (150), a cam guide (165) is arranged on the fixed seat (164), the cam guide (165) is abutted against the side wall surface of the power disc (156), and the power disc (156) rotates together;

eight of the number of conveying troughs (175) are arrayed in equally spaced angular rings on the circumference of the wire feed disc (170).