CN112660482A

CN112660482A - Trisection type distribution equipment used before pressure welding of high-thickness copper bars

Info

Publication number: CN112660482A
Application number: CN202011526604.1A
Authority: CN
Inventors: 夏坤财
Original assignee: Wuhu Hengkun Auto Parts Co Ltd
Current assignee: Wuhu Guotian Automotive Parts Manufacturing Co ltd
Priority date: 2020-12-22
Filing date: 2020-12-22
Publication date: 2021-04-16
Anticipated expiration: 2040-12-22
Also published as: CN112660482B

Abstract

The invention relates to a trisection type distribution device before pressure welding of a high-thickness copper bar, which comprises a workbench, wherein a transverse material channel pipe and a longitudinal material channel pipe are respectively arranged on the workbench; a driving frame is slidably arranged in the transverse material channel pipe; the driving frame is connected with an auxiliary assembly; the auxiliary component is matched with a rocker, and the rocker is connected with a driving component; the drive assembly comprises a drive wheel; the driving wheel is provided with a composite groove which is matched with a diamond block in a sliding way, and the diamond block is matched with a lifting assembly component which is matched with the longitudinal material pipeline in a sliding way; and three collecting boxes are arranged beside the right side of the workbench. The copper bar distributing device is reasonable in structural design, on the basis of utilizing gravity and controlling the driving frame to slide in a left-right reciprocating intermittent manner to distribute copper bars one by one, the main branch pipe is controlled to slide up and down regularly in a distributing intermittent period, so that the pipe replacement and abutting function is realized, the copper bars are automatically and uniformly distributed in number in three collecting boxes, and the copper bar distributing device has high practical value.

Description

Trisection type distribution equipment used before pressure welding of high-thickness copper bars

Technical Field

The invention relates to the field of mechanical conveying equipment, in particular to a trisection type distribution device before pressure welding of a high-thickness copper bar.

Background

Pressure welding is a welding method in which a certain pressure is applied to a combined weldment in a heated or unheated state to cause plastic deformation or melting, and atoms on two separated surfaces are connected by forming a metal bond through recrystallization, diffusion and the like. In the new energy automobile field, the new energy battery technique is the key technology, and the copper bar is then one of the core component on the new energy battery, add man-hour at actual production, need carry out large-scale pressure welding installation work to the copper bar that thickness is thick, current workshop can set up three equipment usually and carry out the pressure welding work, in order to ensure the synchronism of three equipment processing, must evenly divide into the triplex with the big batch copper bar of required processing earlier, adorn in three collecting box, so that send these three collecting box respectively to three equipment departments and carry out the feed, but how the problem can make things convenient for to distribute big batch copper bar in the mode that the quantity is impartial in these three collecting box.

Disclosure of Invention

The invention provides a three-part distribution device before pressure welding of high-thickness copper bars, aiming at realizing the convenience of uniformly distributing the copper bars into three collecting boxes.

The technical problem to be solved by the invention is realized by adopting the following technical scheme:

the three-part distribution equipment before the pressure welding of the high-thickness copper bar comprises a workbench, wherein a transverse material channel pipe and a longitudinal material channel pipe are respectively arranged on the workbench; a driving frame is slidably arranged in the transverse material channel pipe; the driving frame is connected with an auxiliary assembly; the auxiliary component is matched with a rocker, and the rocker is connected with a driving component; the drive assembly comprises a drive wheel; the driving wheel is provided with a composite groove which is matched with a diamond block in a sliding way, and the diamond block is matched with a lifting assembly component which is matched with the longitudinal material pipeline in a sliding way; and three collecting boxes are arranged beside the right side of the workbench.

The upper side of the middle part of the transverse material channel pipe is communicated with a material feeding channel; the lower end of the right side of the transverse material pipe is provided with a sinking port; and a vertically through placing groove is formed in the right side of the driving frame.

The workbench is provided with a horizontal groove, the auxiliary assembly comprises a bending frame in horizontal sliding fit with the horizontal groove, the upper end of the bending frame is connected with the driving frame, the lower end of the bending frame is fixedly connected with a linkage frame, and the linkage frame is provided with a linkage groove in sliding fit with the rocker.

The linkage groove is formed by a straight line groove and a semicircular arc groove which are communicated end to end.

The driving assembly further comprises a motor arranged on the lower side of the workbench, and the driving wheel and the rocker are both arranged on a shaft of the motor; the composite groove comprises three concentric circular grooves; a spiral expansion groove communicated with each circular groove and one circular groove at the radial outer side of the circular groove are arranged between the circular grooves; a radial crossing groove communicated with the annular groove at the outermost side and the annular groove at the innermost side is arranged between the annular groove at the outermost side and the annular groove at the innermost side. The spiral expansion grooves are provided with two, and the radial spanning groove is communicated with the two spiral expansion grooves.

The left end of the longitudinal material channel pipe is provided with a receiving pipe part which is abutted against the lower end of the right side of the transverse material channel pipe; the lifting assembly component comprises a main branch pipe, and the left end of the main branch pipe is abutted to the receiving pipe part; the lower end of the main shunting pipe is connected with a linkage rod, and the lower end of the linkage rod is hinged with a diamond block.

The side wall of the longitudinal material channel pipe is provided with a guide groove for vertically and slidably mounting the main branch channel pipe; the main branch pipe is composed of three branch pipes which are vertically arranged and fixedly connected with each other two by two; the right sides of the three distributing branch pipes are respectively positioned right above the corresponding three collecting boxes.

The invention has the beneficial effects that:

the copper bar distributing device is reasonable in structural design, on the basis of utilizing gravity and controlling the driving frame to slide in a left-right reciprocating intermittent manner to distribute copper bars one by one, the main branch pipe is controlled to slide up and down regularly in a distributing intermittent period, so that the pipe replacement and abutting function is realized, the copper bars are automatically and uniformly distributed in number in three collecting boxes, and the copper bar distributing device has high practical value.

Drawings

The invention is further illustrated with reference to the following figures and examples.

FIG. 1 is a front view of the present invention;

FIG. 2 is a top view of the present invention;

FIG. 3 is a first perspective view of the present invention;

FIG. 4 is a schematic perspective view of the present invention;

FIG. 5 is an enlarged view of a portion of FIG. 3 at I;

FIG. 6 is a partial enlarged view at II of FIG. 3;

FIG. 7 is an enlarged view of a portion of FIG. 3 at III;

FIG. 8 is an enlarged view of a portion of FIG. 3 at IV;

FIG. 9 is a top view of the present invention with three collection boxes removed;

FIG. 10 is a sectional view A-A of FIG. 9;

fig. 11 is a sectional view B-B of fig. 9.

In the figure: 1. a work table; 2. a transverse feed channel pipe; 3. a longitudinal material channel pipe; 4. a driving frame; 5. a rocker; 6. a drive wheel; 7. diamond-shaped blocks; 8. a collection box; 9. a feed channel; 10. a bending frame; 11. a linkage frame; 12. a motor; 13. a main branch pipe; 14. a linkage rod.

Detailed Description

In order to make those skilled in the art better understand the technical solution of the present invention, the present invention will be described more clearly and more completely with reference to the drawings in the following embodiments, and it is understood that the described embodiments are only a part of the present invention, rather than all of the present invention, and based on the embodiments, other embodiments obtained by those skilled in the art without inventive exercise are within the protection scope of the present invention.

As shown in fig. 1 to 11, the trisection type distribution equipment before pressure welding of the high-thickness copper bar comprises a workbench 1, wherein a transverse material pipe 2 and a longitudinal material pipe 3 are respectively arranged on the workbench 1; a driving frame 4 is arranged in the transverse material channel pipe 2 in a sliding way; the driving frame 4 is connected with an auxiliary assembly; the auxiliary component is matched with a rocker 5, and the rocker 5 is connected with a driving component; the drive assembly comprises a drive wheel 6; the driving wheel 6 is provided with a composite groove, the composite groove is in sliding fit with a diamond 7, and the diamond 7 is matched with a lifting assembly component in sliding fit with the longitudinal feed channel pipe 3; and three collecting boxes 8 are arranged beside the right side of the workbench 1.

The upper side of the middle part of the transverse material channel pipe 2 is communicated with a material feeding channel 9; the lower end of the right side of the transverse material pipe 2 is provided with a lower sinking port 2 a; a vertically through placing groove 4a is arranged on the right side of the driving frame 4.

The workbench 1 is provided with a horizontal groove 1a, the auxiliary assembly comprises a bending frame 10 in horizontal sliding fit with the horizontal groove 1a, the upper end of the bending frame 10 is connected with the driving frame 4, the lower end of the bending frame 10 is fixedly connected with a linkage frame 11, and the linkage frame 11 is provided with a linkage groove 11a in sliding fit with the rocker 5.

The linkage groove 11a is formed by a straight line groove and a semicircular arc groove which are communicated end to end.

The driving assembly also comprises a motor 12 arranged on the lower side of the workbench 1, and the driving wheel 6 and the rocker 5 are arranged on the shaft of the motor 12; the composite groove comprises three concentric circular grooves 6 a; a spiral expansion groove 6b communicated with each annular groove 6a and one annular groove 6a on the radial outer side of the annular groove 6a is arranged between the two annular grooves; a radial spanning groove 6c communicated with the outermost annular groove 6a and the innermost annular groove 6a is arranged between the outermost annular groove 6a and the innermost annular groove 6 a. The spiral expansion groove 6b has two, and the radial spanning groove 6c communicates with both of the spiral expansion grooves 6 b.

The left end of the longitudinal material channel pipe 3 is provided with a receiving pipe part 3a which is abutted against the lower end of the right side of the transverse material channel pipe 2; the lifting assembly component comprises a main branch pipe 13, and the left end of the main branch pipe 13 is abutted with the receiving pipe part 3 a; the lower end of the main shunting pipe 13 is connected with a linkage rod 14, and the lower end of the linkage rod 14 is hinged with the diamond 7.

The side wall of the longitudinal material channel pipe 3 is provided with a guide groove 3a for vertically and slidably mounting the branch main pipe 13; the branch main pipe 13 is composed of three branch pipes 13a which are vertically arranged and are fixedly connected with each other two by two; the right sides of the three branch material pipes 13a are respectively positioned right above the corresponding three collecting boxes 8.

In the initial state, the left end of the uppermost branch pipe 13a abuts against the receiving pipe portion 3 a.

Before specifically using, the manual work only needs to put into feedstock channel 9 with the mode that vertically stacks one by one with high thickness copper bar, and wherein, a copper bar of downside is located standing groove 4 a.

When the folding type folding table is used, the shaft of the motor 12 is driven to rotate, on one hand, the rocker 5 is driven to rotate, wherein when the front part of the rocker 5 is positioned in the arc groove of the linkage groove 11a to slide, the linkage frame 11, the bending frame 10 and the driving frame 4 are all static, and when the front part of the rocker 5 is positioned in the linear groove of the linkage groove 11a to slide, the linkage frame 11, the bending frame 10 and the driving frame 4 can slide rightwards firstly and then leftwards. When the driving frame 4 slides rightwards to the right limit position, the copper bar in the placing groove 4a automatically falls into the bearing pipe part 3 a.

On the other hand, when the driving wheel 6 rotates, the diamond blocks 7 slide in the composite grooves relatively, when the diamond blocks 7 slide in any circular groove 6a, the whole branch main pipe 13 is static, in the process, the copper bar at the lowest side originally slides rightwards along with the driving frame 4 and falls into the receiving pipe part 3a, moves rightwards under the action of gravity and slides into a corresponding branch pipe 13a, and continuously slides rightwards under the action of gravity into the corresponding collecting box 8, so that one-time distribution is completed. In addition, when the diamond 7 is positioned in any spiral expanding groove 6b to slide, the linkage rod 14 and the branch header pipe 13 both slide upwards, namely, one branch pipe 13a at the lower side of the branch pipe 13a which originally abuts against the receiving pipe part 3a becomes to abut against the receiving pipe part 3 a; when the diamond block 7 is positioned in the radial crossing groove 6c to slide, the linkage rod 14 and the branch header 13 both slide downwards, so that the original uppermost branch pipe 13a abuts against the receiving pipe part 3a to be changed into the lowermost branch pipe 13a abutting against the receiving pipe part 3 a. The copper bar is replaced and abutted in the intermittent period of copper bar distribution, so that the copper bar is uniformly distributed into the three collecting boxes 8 one by one.

The foregoing shows and describes the general principles, essential features, and advantages of the invention. It will be understood by those skilled in the art that the present invention is not limited to the embodiments described above, which are merely illustrative of the principles of the invention, but that various changes and modifications may be made without departing from the spirit and scope of the invention, which fall within the scope of the invention as claimed. The scope of the invention is defined by the appended claims and equivalents thereof.

Claims

1. Trisection formula delivery equipment before high thickness copper bar pressure welding, including workstation (1), its characterized in that: a transverse material channel pipe (2) and a longitudinal material channel pipe (3) are respectively arranged on the workbench (1); a driving frame (4) is arranged in the transverse material channel pipe (2) in a sliding way; the driving frame (4) is connected with an auxiliary assembly; the auxiliary component is matched with a rocker (5), and the rocker (5) is connected with a driving component; the drive assembly comprises a drive wheel (6); the driving wheel (6) is provided with a composite groove, the composite groove is in sliding fit with a diamond block (7), and the diamond block (7) is matched with a lifting assembly component in sliding fit with the longitudinal feed channel pipe (3); and three collecting boxes (8) are arranged beside the right side of the workbench (1).

2. The pre-bonding trisection dispensing apparatus of high thickness copper bars as recited in claim 1 further comprising: the upper side of the middle part of the transverse material channel pipe (2) is communicated with a material feeding channel (9); the lower end of the right side of the transverse material pipe (2) is provided with a sinking port (2 a); a vertically through placing groove (4a) is arranged on the right side of the driving frame (4).

3. The pre-bonding trisection dispensing apparatus of high thickness copper bars as recited in claim 1 further comprising: the workbench (1) is provided with a horizontal groove (1a), the auxiliary assembly comprises a bending frame (10) which is in horizontal sliding fit with the horizontal groove (1a), the upper end of the bending frame (10) is connected with the driving frame (4), the lower end of the bending frame (10) is fixedly connected with a linkage frame (11), and the linkage frame (11) is provided with a linkage groove (11a) which is in sliding fit with the rocker (5).

4. The pre-bonding trisection dispensing apparatus of high thickness copper bars as claimed in claim 3 wherein: the linkage groove (11a) is formed by a straight line groove and a semicircular arc groove which are communicated end to end.

5. The pre-bonding trisection dispensing apparatus of high thickness copper bars as claimed in claim 3 wherein: the driving assembly further comprises a motor (12) arranged on the lower side of the workbench (1), and the driving wheel (6) and the rocker (5) are arranged on a shaft of the motor (12); the composite groove comprises three concentric circular ring grooves (6 a); a spiral expansion groove (6b) communicated with each annular groove (6a) and one annular groove (6a) at the radial outer side of the annular groove (6a) are arranged between the two annular grooves; a radial spanning groove (6c) communicated with the outermost annular groove (6a) and the innermost annular groove (6a) is arranged between the outermost annular groove (6a) and the innermost annular groove.

6. The pre-bonding trisection dispensing apparatus of high thickness copper bars as claimed in claim 5, wherein: the left end of the longitudinal material channel pipe (3) is provided with a bearing pipe part (3a) which is abutted against the lower end of the right side of the transverse material channel pipe (2); the lifting assembly component comprises a main branch pipe (13), and the left end of the main branch pipe (13) is abutted against the bearing pipe part (3 a); the lower end of the main shunting pipe (13) is connected with a linkage rod (14), and the lower end of the linkage rod (14) is hinged with the diamond block (7).

7. The pre-bonding trisection dispensing apparatus of high thickness copper bars as recited in claim 6 further comprising: the side wall of the longitudinal material channel pipe (3) is provided with a guide groove (3a) for vertically and slidably mounting the main branch pipe (13); the main branch pipe (13) is composed of three branch pipes (13a) which are vertically arranged and fixedly connected with each other two by two; the right sides of the three distributing branch pipes (13a) are respectively positioned right above the corresponding three collecting boxes (8).