CN210048258U - Subtract copper feed mechanism - Google Patents

Abstract

The utility model discloses a copper-reducing feeding mechanism, which comprises a frame, and a plate placing rotating shaft group, a plate entering pressing strip and a lifting rotating shaft group which are sequentially arranged along the feeding sequence, wherein the plate placing rotating shaft group comprises N groups which are horizontally arranged on the frame, and each row is provided with two plate placing rotating shafts which are arranged at intervals; the board entering pressing strips are arranged on the rear side of the board placing rotating shaft group and form N pressing strips, each pressing strip corresponds to one board placing rotating shaft group, and the N pressing strips can be opened and closed independently; the lifting rotating shaft groups are N in number and are sequentially positioned at the rear side of the board entering pressing bar, and the N lifting rotating shaft groups correspond to the N board placing rotating shaft groups one by one; n is more than or equal to 2. The utility model has the advantages that: n rolls of materials are simultaneously placed at the production moment; in addition, the number of the plate-entering pressing strips 3 is N, and the plate-entering pressing strips can be opened and closed independently, so that the plate-entering pressing strips are convenient to operate independently; in addition, 2 lifting rotating shafts are arranged in each row, and the N rolls of materials are lifted twice to enable the material receiving time to be long, so that the operation is convenient.

Description

Subtract copper feed mechanism

Technical Field

The utility model relates to a subtract technical field of copper technology, concretely relates to subtract copper feed mechanism.

Background

The existing copper-reducing feeding mechanism generally has two rows of incoming line lines, each row is only provided with 1 plate placing rotating shaft, and when a plate is placed, a roll can be placed only after a previous roll is placed and a roller is dismounted, so that the operation is inconvenient; only one lifting reel is arranged in each row, so that the lifting time period and the wiring time are short, and the operation is inconvenient (the linear speed is 3.3m/min, the lifting height is 0.75m, and the lifting time is 13 s); meanwhile, the pressing strips for pressing the copper wires are arranged for the whole copper wire, two lines are pressed simultaneously, and one line cannot be controlled and operated independently. Therefore, the existing feeding mechanism can only carry out simultaneous feeding and discharging in two rows or use single-row production when feeding the upper plate, and the copper is reduced simultaneously in two rows, so that the operation is inconvenient in one row. When the new line is produced, two rows of the material receiving devices are convenient to receive and have long material receiving time when being produced simultaneously.

SUMMERY OF THE UTILITY MODEL

The utility model discloses the main technical problem who solves provides a subtract copper feed mechanism.

A copper reduction feed mechanism, comprising: the frame reaches and sets gradually along the material loading order put the board pivot group in the frame, go into the board layering and go up and down the pivot group, wherein:

the plate placing rotating shaft group comprises N groups which are horizontally arranged on the rack, and two plate placing rotating shafts which are arranged at intervals are formed in each row;

the plate entering pressing strips are arranged at the rear side of the plate placing rotating shaft group and form N pressing strips, each pressing strip corresponds to one plate placing rotating shaft group, and the N pressing strips can be independently opened and closed;

the lifting rotating shaft groups are N in number and are sequentially positioned at the rear side of the board entering pressing bar, and the N lifting rotating shaft groups correspond to the N board placing rotating shaft groups one by one;

N≥2。

the utility model has the advantages that: n rolls of materials are simultaneously placed at the production moment; in addition, the number of the plate-entering pressing strips 3 is N, and the plate-entering pressing strips can be opened and closed independently, so that the plate-entering pressing strips are convenient to operate independently; in addition, 2 lifting rotating shafts are arranged in each row, and the N rolls of materials are lifted twice to enable the material receiving time to be long, so that the operation is convenient.

Drawings

Fig. 1 is a schematic structural view of a copper-reducing feeding mechanism of the present invention;

FIG. 2 is a side view of the set of the plate-placing rotating shafts;

fig. 3 is a schematic structural view of the entry-board pressing strip.

Detailed Description

The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative work all belong to the protection scope of the present invention.

Referring to fig. 1, a copper-reducing feeding mechanism 100 includes: frame 1 and along the material loading order set gradually put board pivot group 2, income board layering 3 and lift pivot group 4 in frame 1, wherein:

the plate placing rotating shaft group 2 comprises N groups which are horizontally arranged on the rack 1, and each group is provided with two plate placing rotating shafts 21 which are arranged at intervals;

the plate entering pressing strips 3 are arranged at the rear side of the plate placing rotating shaft group 2 and form N pressing strips 32, each pressing strip 32 corresponds to one plate placing rotating shaft group 2, and the N pressing strips 32 can be independently opened and closed;

the lifting rotating shaft groups 4 are N in number and are sequentially positioned at the rear side of the board entering pressing bar 3, the N lifting rotating shaft groups 4 correspond to the N rows of board placing rotating shaft groups 2 one by one, each lifting rotating shaft group 4 comprises two lifting rotating shafts 41 positioned at the lower part and two lifting rotating shafts 42 positioned at the upper part, and the coil stock is transmitted on the four lifting rotating shafts 41 to form an N shape;

N≥2。

according to the copper-reducing feeding mechanism, N rolls of materials are simultaneously discharged at the production moment; in addition, the number of the plate-entering pressing strips 3 is N, and the plate-entering pressing strips can be opened and closed independently, so that the plate-entering pressing strips are convenient to operate independently; in addition, 2 lifting rotating shafts are arranged in each row, and the N rolls of materials are lifted twice to enable the material receiving time to be long, so that the operation is convenient.

The copper reduction feed mechanism is described in detail below.

The copper reduction feeding mechanism is provided with a rack 1, a plate placing rotating shaft group 2, a plate entering pressing strip 3 and a lifting rotating shaft group 4, wherein a material is wound on the plate placing rotating shaft group 2 and is compacted through the plate entering pressing strip 3 and is connected with the material through the lifting rotating shaft group 4.

Put the pan feeding pivot group 2 setting in frame 1 and hold, go into the setting of board layering 3 and put the rear side of board pivot group 2, go up and down pivot group 4 setting in the rear side of pan feeding layering 3.

Put a board pivot group 2 and include N, N put a board pivot group 2 and set up in frame 1 along the horizontal direction, and arbitrary two coil stock on putting board pivot group 2 mutually noninterfere.

That is, when the material is wound on any of the set of the laying-off rotating shafts 2, the material does not intersect with the material of the other set of the laying-off rotating shafts 2' while moving in the feeding sequence.

Generally, the coil is wound on the end of the set of the plate-releasing rotating shafts 2, so that the lengths of the N sets of the plate-releasing rotating shafts are different, and the coil on any two sets of the plate-releasing rotating shafts do not interfere with each other.

Further, the length of the N plate placing rotating shaft groups along the feeding sequence is gradually increased or gradually decreased. As shown in fig. 2, the upper set of the plate-releasing rotating shafts 2 and the lower set of the plate-releasing rotating shafts 2' have different lengths, so that they will not interfere with each other when rolling.

Each set 2 of the plate placing rotating shafts comprises two plate placing rotating shafts 21 with equal length which are arranged in tandem and are positioned at different heights.

As shown in fig. 3, the entrance batten 3 includes a bracket 31 and battens 32, the length of the bracket 31 corresponds to the length of the longest slat placing rotating shaft group, and the number of the battens 32 is N, and the battens are hinged to the bracket 31 in parallel along the length direction of the bracket 31.

The support 31 is provided with N hinges, and one ends of the N pressing strips 32 are connected to the hinges. Meanwhile, the N pressing strips 32 correspond to the N plate-placing rotating shaft groups 2 one by one. Namely, each pressing strip 32 can press the coil conveyed by one plate placing rotating shaft group 2 through the turning of the hinge. Any number of rolls can be pressed simultaneously by turning any number of hinges.

With reference to fig. 2 and 3, the coil guided out by the upper set of plate-placing rotating shafts 2 correspondingly penetrates through the left press strip 32A, and the coil guided out by the lower set of plate-placing rotating shafts 2' correspondingly penetrates through the right press strip 32B, which are not interfered with each other.

N groups of sliding grooves 10 in the vertical direction are formed in the rear of the board entering pressing strip 3 of the rack 1, a positioning device is arranged in each group of sliding grooves 10, each positioning device is connected with one lifting rotating shaft group 4, and the positioning device controls the height of the lifting rotating shaft group 4.

It should be noted that the positioning device may use a screw, and the screw is inserted into the lifting rotating shaft group 4 and screwed into the sliding groove, so as to fix the lifting rotating shaft group 4.

Further, each lifting rotating shaft group 4 includes two lifting rotating shafts 41 located at the lower part and two lifting rotating shafts 42 located at the upper part, and the coil stock forms an "N" shape when the four lifting rotating shafts 41 are transmitted. The positioning device controls the height of the four lifting reels 41 (42).

Preferably, the two lower lifting shafts 41 are fixed by a positioning device, and are located at

The N lifting rotating shaft groups 4 correspond to the N pressing strips 32, and the length of any lifting rotating shaft group 4 corresponds to the distance from one pressing strip 32 to the rack 1. That is, the coil stock passing through any pressing strip 32 passes through the corresponding lifting rotating shaft group along the direction parallel to the machine frame 1.

In the above embodiment, N is preferably 2. Two groups of coil materials can be simultaneously carried out.

The above-mentioned embodiments only express the embodiments of the present invention, and the description thereof is more specific and detailed, but not construed as limiting the scope of the utility model. It should be noted that, for those skilled in the art, without departing from the spirit of the present invention, several variations and modifications can be made, which are within the scope of the present invention. Therefore, the protection scope of the present invention should be subject to the appended claims.

Claims (10)

1. The utility model provides a subtract copper feed mechanism, includes the frame and sets gradually along the material loading order put the board pivot group in the frame, go into the board layering and go up and down the pivot group, its characterized in that:

the plate placing rotating shaft group comprises N groups which are horizontally arranged on the rack, and two plate placing rotating shafts which are arranged at intervals are formed in each row;

the plate entering pressing strips are arranged at the rear side of the plate placing rotating shaft group and form N pressing strips, each pressing strip corresponds to one plate placing rotating shaft group, and the N pressing strips can be independently opened and closed;

the lifting rotating shaft groups are N in number and are sequentially positioned at the rear side of the board entering pressing bar, and the N lifting rotating shaft groups correspond to the N board placing rotating shaft groups one by one;

N≥2。

2. the copper reducing feeding mechanism according to claim 1, wherein N of the turning shaft sets are arranged on the frame 1 along a horizontal direction, and the coil materials on any two turning shaft sets do not interfere with each other.

3. The copper-reducing feeding mechanism as claimed in claim 2, wherein the lengths of the N sets of the turning shafts of the placing plates along the feeding sequence are gradually increased or gradually decreased.

4. The copper-reducing feeding mechanism as claimed in claim 2 or 3, wherein each of the plate-placing rotating shaft sets comprises two plate-placing rotating shafts with equal length in tandem, and the two plate-placing rotating shafts are located at different heights.

5. The copper-reducing feeding mechanism according to claim 4, wherein the board-entering pressing strips comprise supports and pressing strips, the length of each support corresponds to the length of the longest board-placing rotating shaft group, and the pressing strips are hinged to the supports in a number of N in parallel along the length direction of the supports.

6. The copper reducing feeding mechanism according to claim 5, wherein N hinges are arranged on the support, one ends of N pressing strips are connected to the hinges, each pressing strip can press a coil conveyed by one of the plate placing rotating shaft groups through the turning of the hinge, and N is 2.

7. The copper-reducing feeding mechanism according to claim 1, wherein the rack is provided with N sets of sliding grooves in the vertical direction behind the inlet plate pressing strip, each set of sliding grooves is internally provided with a positioning device, each positioning device is connected with one lifting rotating shaft set, and the positioning devices control the heights of the lifting rotating shaft sets.

8. The copper-reducing feeding mechanism according to claim 7, wherein each of the lifting rotating shaft groups includes two lifting rotating shafts located at a lower portion and two lifting rotating shafts located at an upper portion, and the four lifting rotating shafts are arranged in a front-rear direction and form an "N" shape.

9. The copper-reducing feeding mechanism as claimed in claim 7 or 8, wherein the length of the lifting rotating shaft group corresponds to the distance between the pressing strips and the rack in a one-to-one manner.

10. The copper reduction feed mechanism of claim 8, wherein N is 2.

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