CN210754829U - Flat wire metal material turns over a equipment - Google Patents

Abstract

The utility model discloses a flat line metal material turns over a equipment and includes: the device comprises a fixed supporting structure, a rotating structure, a shaping device, a feeding device and a turnover device. Wherein the fixed support structure is provided with a plurality of rotating structures; the shaping device and the feeding device are connected between two adjacent rotating structures, the shaping device and the feeding device synchronously rotate along with the rotating structures, and the shaping device and the feeding device are arranged along the flat wire metal feeding direction; the shaping device is used for shaping the flat wire metal, and the feeding device is used for feeding the flat wire metal; the turnover device is fixed on the fixed supporting structure and sleeved on the rotating structure and used for driving the rotating structure to rotate. The utility model discloses can follow the feeding, give, the plastic is accomplished together, and degree of automation is high, no longer need manual a flat line wire rod that turns over, it buckles required automation angle and turns over a equipment to have overcome not to adapt to the flat line among the prior art to lead to the technical problem that can not accomplish complicated manufacturing requirement.

Description

Flat wire metal material turns over a equipment

Technical Field

The utility model relates to a mechanical automation field, specifically speaking relates to a be used for flat line metal material to turn over a equipment.

Background

The flat wire metal has a large cross-sectional area, and is widely applied in the electrical field. For example, it is essential to connect a battery string of an electric vehicle. In some application fields, the flat wire metal is required to be bent according to a certain angle and direction due to the reason of flat wire metal wiring. The existing traditional flat wire metal bending is completed by semi-automatic manual operation and certain equipment. The semi-automatic mode has low efficiency on one hand, and on the other hand, the manual feeding can not ensure the precision, so that larger errors can exist, and the requirements in the field of precision manufacturing can not be met. Therefore, it is necessary to develop a device capable of bending the flat wire metal, but when the device is bent, the device needs to be adjusted according to the horizontal and vertical directions of the flat wire metal, for example, the device needs to be bent to the left side in the horizontal direction relative to the flat wire metal, or needs to be bent to the right side in the vertical direction relative to the flat wire metal at another moment.

According to the above, in order to meet the complicated manufacturing requirements when the flat wire metal is bent, an automatic folding device adapted to the flat wire metal needs to be provided to realize the angle folding of the flat wire metal.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to provide a flat line metal material turns over a equipment, aim at solving and do not adapt to the flat line and buckle required automation angle and turn over a equipment among the prior art to lead to the technical problem that can not accomplish complicated manufacturing requirement.

The utility model provides a flat line metal material turns over a equipment, include: the fixed support structure comprises a plurality of rotation positioning points, and each rotation positioning point is provided with a rotation structure; the shaping device and the feeding device are connected between two adjacent rotating structures, the shaping device and the feeding device synchronously rotate along with the rotating structures, the shaping device and the feeding device are arranged along the feeding direction of the flat wire metal, and the flat wire metal sequentially passes through the shaping device and the feeding device and is fed out from the outermost rotating structure; the shaping device is used for shaping the flat wire metal, and the feeding device is used for feeding the flat wire metal;

one end of the turnover device is fixed on the fixed supporting structure, the other end of the turnover device is sleeved on any one of the rotating structures and used for driving the rotating structures to rotate, and the turnover device is used for rotating the rotating structures.

The utility model discloses a flat line metal material turns over a equipment shaping device and gives the device and pass through revolution mechanic and be connected to make shaping device, give the device as a whole and use revolution mechanic as the axis of rotation for fixed bearing structure is rotatory, wherein, under the drive of turning over a device, can make whole linear structure together rotatory, shaping device and give the device respectively still can keep independent work simultaneously when rotatory, can not influence work. This flat wire metal material turns over a equipment flat wire metal material and turns over and turn over equipment flat wire metal material can be followed the feeding, gives, and the plastic is all accomplished in this equipment, and degree of automation is high, no longer need manually turn over a flat wire metal wire rod, has overcome and has not adapted to the flat wire and has buckled required automatic angle among the prior art and turn over a equipment to lead to can not accomplishing the technical problem of complicated manufacturing requirement.

Drawings

Fig. 1 and 2 are schematic views of the overall structure of the present invention;

fig. 3 and 4 are schematic views of a first shaping structure of the present invention;

fig. 5 and 6 are schematic diagrams of a second reshaping structure of the present invention;

fig. 7 and 8 are schematic structural views of a feeding device according to the present invention;

fig. 9 and 10 are schematic structural views of the folding device of the present invention.

Description of reference numerals:

A. rotating the positioning point; B. flat wire metal; 100. fixing the support structure; 11. a housing; 110. a vertical plate; 12. a support member; 200. a rotating structure; 300. a shaping device; 31. fixing the connecting plate; 32. a first shaping structure; 321. a first structural member; 3211. a first accommodating groove; 322. a first slider; 323. a first support spring; 324. a first rolling bearing wheel; 3241. a first inner groove; 325. a first fastening strip; 326. A first adjusting screw; 33. a second shaping structure; 331 a second structural member; 3311. a second accommodating groove; 332. A second slider; 333. a second support spring; 334. a second rolling bearing wheel; 3341. a second inner groove; 335. a second fastening strip; 336. a second adjusting screw; 337. a third rolling bearing wheel; 400. feeding to a device; 41. a box body; 42. a first bearing wheel set; 43. a second bearing wheel set; 401. a sub-bearing wheel; 431. a third accommodating groove; 432. a third slider, 433, a third adjusting screw; 434. a third support spring; 44. a drive structure; 441. a drive gear set; 500. a turnover device; 51. a fixing box; 52. a drive motor; 521. a drive gear; 53. a speed reducer; 54. a rotating wheel.

Detailed Description

The invention will be further elucidated and described with reference to the following embodiments and drawings in which:

referring to fig. 1 and 2, the present invention discloses a flat wire metal material folding apparatus, including: a fixed support structure 100, a shaping device 300, a feeding device 400, and a turnover device 500. Wherein,

the fixed supporting structure 100 comprises a plurality of rotation positioning points A, and each rotation positioning point A is provided with a rotation structure 200;

the shaping device 300 and the feeding device 400 are connected between two adjacent rotating structures 200, the shaping device 300 and the feeding device 400 rotate along with the rotating structures 200 synchronously, the shaping device 300 and the feeding device 400 are arranged along the feeding direction of the flat wire metal, and the flat wire metal passes through the shaping device 300 and the feeding device 400 in sequence and is fed out from the outermost rotating structure 200; the shaping device 300 is used for shaping the flat wire metal, and the feeding device 400 is used for feeding the flat wire metal;

one end of the turnover device 500 is fixed to the fixed supporting structure 100, the other end of the turnover device is sleeved on any one of the rotating structures 200 and used for driving the rotating structure 200 to rotate, and the turnover device 500 is used for rotating the rotating structure 200.

The utility model discloses a flat line metal material turns over a equipment shaping device 300 and gives device 400 and pass through revolution mechanic 200 for be connected to make shaping device 300, give device 400 as a whole and use revolution mechanic 200 to rotate for fixed bearing structure 100 for the axis of rotation for device 400, wherein, under the drive of turning over a device 500, can make whole rectilinear structure together rotatory, shaping device 300 and give device 400 separately still can keep independent work simultaneously when rotatory, can not influence work. This flat wire metal material turns over a equipment flat wire metal material and turns over and turn over equipment flat wire metal material can be followed the feeding, gives, and the plastic is all accomplished in this equipment, and degree of automation is high, no longer need manually turn over a flat wire metal wire rod, has overcome and has not adapted to the flat wire and has buckled required automatic angle among the prior art and turn over a equipment to lead to can not accomplishing the technical problem of complicated manufacturing requirement.

Referring to fig. 1 and 2, the fixed support structure 100 includes: a housing 11, a support 12.

Specifically, the housing 11 has a pair of opposing risers 110; the supporting piece 12 is positioned outside the two shells 11; the two vertical plates 110 and the supporting member 12 are provided with 3 rotation positioning points a, and the rotation positioning points a are located on the same straight line.

In this embodiment, the 3 rotation positioning points a realize a two-stage structure, the shaping device 300 and the feeding device 400 are respectively disposed between two adjacent rotation positioning points a, wherein both the shaping device 300 and the feeding device 400 are connected to the rotation structure 200, and the two devices rotate synchronously.

Referring to fig. 1 and 2, the shaping device 300 includes: the device comprises a fixed connecting plate 31, a first shaping structure 32 and a second shaping structure 33, wherein two ends of the fixed connecting plate 31 are respectively connected to the rotating structures 200 on two adjacent rotating positioning points A; the first reshaping structure 32 and the second reshaping structure 33 are fixed on the fixed connecting plate 31.

Two ends of the fixed connecting plate 31 are respectively connected to the two rotating structures 200, the fixed connecting plate 31 rotates along with the rotating structures 200, and the length extending direction of the fixed connecting plate 31 is the same as the metal feeding direction of the flat wire; the first shaping structure 32 and the second shaping structure 33 are sequentially fixed on the fixed connecting plate 31 along the length direction of the flat wire metal, the flat wire metal sequentially passes through the first shaping structure 32 and the second shaping structure 33, the first shaping structure 32 is used for shaping the flat wire metal in the horizontal transverse direction, and the second shaping structure 33 is used for shaping the flat wire metal in the vertical direction perpendicular to the horizontal direction; the first shaping structure 32 is horizontally disposed, and the second shaping structure 33 is vertically disposed with respect to the first shaping structure 32.

Referring to fig. 3 and 4, the first shaping structure 32 includes: a first structural member 321, a plurality of first sliders 322, a first support spring 323, a first rolling bearing wheel 324, two first fastening strips 325, and a first adjusting screw 326. In particular, the method comprises the following steps of,

the first structural member 321 is a planar strip, two rows of first receiving grooves 321 are respectively formed in two sides of the first structural member 321 along the length direction, and the two rows of first receiving grooves 321 are distributed in a staggered manner, so that the first structural member 321 is in a square sawtooth shape;

the first sliding member 322 is disposed in each of the first receiving grooves 321, and slides in the first receiving grooves 321;

the first supporting spring 323 is disposed between the bottom of the first sliding member 322 and the end surface of the first receiving groove 321 away from the side edge, and two ends of the first supporting spring 323 respectively abut against the first sliding member 322 and the first structural member 321;

the first rolling bearing wheels 324 are arranged on the surface of each first sliding piece 322, and each first rolling bearing wheel 324 is provided with a first inner groove along the outer circumferential direction;

the first fastening strips 325 are respectively disposed at two sides of the first structural member 321 in the length direction, and are used for sealing the first accommodating groove 321 of the first sliding member 322;

the plurality of first adjusting screws 326 are disposed on the first fastening strips 325, penetrate through the first fastening strips 325 and abut against each of the first sliding members 322, and are used for adjusting the positions of the first sliding members 322 in the first accommodating grooves 321;

the flat wire metal is located between two adjacent first rolling bearing wheels 324, and is clamped by the first inner grooves of two adjacent first rolling bearing wheels 324.

Referring to fig. 5 and 6, the second shaping structure 33 includes: a second structure 331, a plurality of second sliders 332, a second support spring 333, a second rolling bearing wheel 334, a second fastening strip 335, a third rolling bearing wheel 337. In particular, the method comprises the following steps of,

the second structural member 331 is a planar strip, and a plurality of second accommodating grooves 3311 are formed at intervals on one side of the first structural member 321 along the length direction;

the second sliding member 332 is disposed in each of the second receiving slots 3311 and slides in the second receiving slots 3311;

the second supporting spring 333 is disposed between the bottom of the second sliding member 332 and the end surface of the second receiving slot 3311 away from the side edge, and two ends of the second supporting spring 333 respectively abut against the second sliding member 332 and the second structural member 331;

the second rolling bearing wheels 334 are disposed on the surface of each of the second sliders 332, and each of the second rolling bearing wheels 334 is provided with a second inner groove 3341 along the outer circumferential direction;

the second fastening strip 335 is disposed at one side of the second structural member 331 in the length direction, and is used for sealing the second receiving groove 3311 in which the second sliding member 332 is mounted;

the second adjusting screws 336 are disposed on the second fastening strips 335, penetrate through the second fastening strips 335, and abut against each of the second sliding members 332, and are used for adjusting the positions of the second sliding members 332 in the second accommodating slots 3311;

the third rolling bearing wheel 337 is disposed at the other side of the second structural member 331 in the length direction, and is spaced apart from the second rolling bearing wheel 334;

the flat wire metal is located between the second rolling bearing wheel 334 and the third rolling bearing wheel 337, and is clamped by the first inner grooves of the second rolling bearing wheel 334 and the third rolling bearing wheel 337.

Referring to fig. 7 and 8, the feeding device 400 includes: a case 41, first and second bearing wheel sets 42 and 43, and a driving structure 44; in particular, the method comprises the following steps of,

the box body 41 is arranged between the two rotating structures 200 and is provided with an internal avoiding space, and the avoiding space is used for avoiding the flat wire metal so that the flat wire metal penetrates through the box body 41;

the first bearing wheel set 42 and the second bearing wheel set 43 are arranged in the box body 41 in an upper-lower two-row manner, the first bearing wheel set 42 is positioned on the box body 41, the second bearing wheel set 43 moves relative to the first bearing wheel set 42, the first bearing wheel set 42 and the second bearing wheel set 43 both comprise a plurality of sub bearing wheels 401, the bearing wheels of the first bearing wheel set 42 and the bearing wheels of the second bearing wheel set 43 are opposite to each other, and the flat wire metal is clamped between the two opposite bearing wheels;

the driving structure 44 is fixed on a surface of the box body 41 opposite to the first bearing wheel set 42, and drives the first bearing wheel to rotate through a transmission gear set 441 arranged in the box body 41, so as to drive the flat wire metal clamped between the first bearing wheel set 42 and the second bearing wheel set 43 to be fed.

A row of third receiving grooves 431 is formed in the box 41, the third receiving grooves 431 are used for receiving third sliding pieces 432, the sub-bearing wheel 401 of the second bearing wheel set 43 is positioned on the third sliding pieces 432, the third sliding pieces 432 slide in the third receiving grooves 431, a third adjusting screw 433 is arranged at one end of the third sliding pieces 432 far away from the third supporting spring 434, a third supporting spring 434 is arranged between the third sliding pieces 432 and the third adjusting screw 433, and the third adjusting screw 433 is used for adjusting the position of the third sliding pieces 432 in the third receiving grooves 431.

Referring to fig. 9 and 10, the folding device 500 includes: a stationary box 51, a driving motor 52, a decelerator 53, and a rotation wheel 54, and, in particular,

the fixed box 51 is fixed to the fixed support structure 100;

the driving motor 52 is connected to the fixed box 51, and a driving gear is provided at an end thereof;

the speed reducer 53 is fixed to the driving motor 52 and connected to the driving gear;

the rotating structure 200 is sleeved outside the rotating structure 200, connected to the speed reducer 53, and configured to drive the rotating structure 200 to rotate along with the operation of the speed reducer 53, so as to drive the shaping device 300 and the feeding device 400 to rotate.

Wherein the rotating structure 200 is a bearing sleeve.

It should be finally noted that the above embodiments are only intended to illustrate the technical solutions of the present invention, and not to limit the scope of the present invention, and although the present invention has been described in detail with reference to the preferred embodiments, it should be understood by those skilled in the art that the technical solutions of the present invention can be modified or replaced with equivalents without departing from the spirit and scope of the technical solutions of the present invention.

Claims (9)

1. The utility model provides a flat wire metal material turns over a equipment which characterized in that includes:

the fixed support structure comprises a plurality of rotation positioning points, and each rotation positioning point is provided with a rotation structure;

the shaping device and the feeding device are connected between two adjacent rotating structures, the shaping device and the feeding device synchronously rotate along with the rotating structures, the shaping device and the feeding device are arranged along the feeding direction of the flat wire metal, and the flat wire metal sequentially passes through the shaping device and the feeding device and is sent out from the outermost rotating structure; the shaping device is used for shaping the flat wire metal, and the feeding device is used for feeding the flat wire metal;

one end of the turnover device is fixed on the fixed supporting structure, the other end of the turnover device is sleeved on any one rotating structure and used for driving the rotating structure to rotate, and the turnover device is used for rotating the rotating structure.

2. The flat wire metal material turn-over apparatus of claim 1, wherein the fixed support structure comprises:

a casing having a pair of opposing risers;

a support member positioned outside the two housings;

two risers and support piece set up 3 rotation locating points altogether, and a plurality of rotation locating points are located same straight line.

3. The flat wire metal material turnover device of claim 2, wherein the shaping means includes:

the two ends of the fixed connecting plate are respectively connected to the two rotating structures, the fixed connecting plate rotates along with the rotating structures, and the length extending direction of the fixed connecting plate is the same as the feeding direction of the flat wire metal;

the first shaping structure and the second shaping structure are sequentially fixed on the fixed connecting plate along the length direction of the flat wire metal, the flat wire metal sequentially passes through the first shaping structure and the second shaping structure, the first shaping structure is used for shaping the flat wire metal in the horizontal transverse direction, and the second shaping structure is used for shaping the flat wire metal in the vertical direction perpendicular to the horizontal direction; the first shaping structure is horizontally arranged, and the second shaping structure is perpendicular to the first shaping structure.

4. The flat wire metal material turn-over apparatus of claim 3, wherein the first shaping structure comprises:

the first structural member is in a plane strip shape, two rows of first accommodating grooves are respectively formed in two sides of the first structural member along the length direction, and the two rows of first accommodating grooves are distributed in a staggered mode, so that the first structural member is in a square sawtooth shape;

the first sliding parts are arranged in each first accommodating groove and slide in the first accommodating grooves;

the first supporting spring is arranged between the bottom of the first sliding piece and the end face, far away from the side edge, of the first accommodating groove, and two ends of the first supporting spring respectively abut against the first sliding piece and the first structural member;

the first rolling bearing wheels are arranged on the surface of each first sliding piece, and each first rolling bearing wheel is provided with a first inner groove along the outer circumferential direction;

the first fastening strips are respectively arranged on two sides of the first structural member in the length direction and used for being hermetically provided with a first accommodating groove of a first sliding piece;

the first adjusting screws are arranged on the first fastening strips, penetrate through the first fastening strips and abut against each first sliding piece, and are used for adjusting the positions of the first sliding pieces in the first accommodating grooves;

the flat wire metal is positioned between two adjacent first rolling bearing wheels and clamped by the first inner grooves of the two adjacent first rolling bearing wheels.

5. The flat wire metal material turn-over device of claim 3 or 4, wherein the second shaping structure comprises:

the second structural part is in a plane strip shape, and a plurality of second accommodating grooves are formed in one side of the first structural part along the length direction at intervals;

the second sliding pieces are arranged in the second accommodating grooves and slide in the second accommodating grooves;

the second supporting spring is arranged between the bottom of the second sliding part and the end face, far away from the side edge, of the second accommodating groove, and two ends of the second supporting spring respectively abut against the second sliding part and the second structural part;

the second rolling bearing wheel is arranged on the surface of each second sliding piece, and a second inner groove is formed in the circumferential direction of the outer side of each second rolling bearing wheel;

the second fastening strip is arranged on one side of the second structural part in the length direction and used for being hermetically provided with a second accommodating groove of the second sliding part;

the second adjusting screws are provided with a plurality of second adjusting screws, are all arranged on the second fastening strips, penetrate through the second fastening strips and abut against each second sliding piece, and are used for adjusting the positions of the second sliding pieces in the second accommodating grooves;

the third rolling bearing wheel is arranged on the other side of the second structural part in the length direction and is arranged at intervals with the second rolling bearing wheel;

the flat wire metal is positioned between the adjacent second rolling bearing wheels and the third rolling bearing wheels and is clamped by the first inner grooves of the adjacent second rolling bearing wheels and the third rolling bearing wheels.

6. The flat wire metal material turn-over apparatus of claim 1, wherein the feeding means comprises:

the box body is arranged between the two rotating structures and is provided with an internal avoiding space which is used for avoiding the flat wire metal so as to enable the flat wire metal to pass through the shell;

the first bearing wheel set and the second bearing wheel set are arranged on the shell in an upper row and a lower row, the first bearing wheel set is positioned on the box body, the second bearing wheel set moves relative to the first bearing wheel set, the first bearing wheel set and the second bearing wheel set respectively comprise a plurality of sub bearing wheels, the bearing wheels of the first bearing wheel set and the bearing wheels of the second bearing wheel set are opposite to each other, and the flat wire metal is clamped between the two opposite bearing wheels;

the driving structure is fixed on one surface of the shell, back to the first bearing wheel set, and drives the first bearing wheel to rotate through the transmission gear set arranged in the shell, so that the flat wire metal clamped between the first bearing wheel set and the second bearing wheel set is driven to be fed.

7. The flat wire metal material folding apparatus according to claim 6, wherein a row of third receiving grooves for receiving a third sliding member is provided in the case, the sub-bearing wheels of the second bearing wheel set are positioned in the third receiving grooves, the third sliding member slides in the third receiving grooves, a third adjusting screw is provided on a side of the third sliding member adjacent to the edge of the case, a third supporting spring is provided between the third sliding member and the third adjusting screw, and the third adjusting screw is used for adjusting the position of the third sliding member in the third receiving grooves.

8. The flat wire metal material turn-over apparatus of claim 1, wherein the turn-over means comprises:

the fixing box is fixed on the fixing support structure;

the driving motor is connected to the fixed box, and a driving gear is arranged at the end part of the driving motor;

the speed reducer is fixed on the driving motor and is connected with the driving gear;

the rotating wheel is sleeved on the outer side of the rotating structure, is connected with the speed reducer and is used for driving the rotating structure to rotate along with the work of the speed reducer, so that the shaping device is driven and the feeding device is driven to rotate.

9. The flat wire metal material turn-over apparatus of claim 1, wherein the rotating structure is a bearing sleeve.

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