CN218878558U - Spacing pay-off subassembly of copper-clad plate production - Google Patents

Abstract

The utility model relates to a spacing pay-off subassembly of copper-clad plate production belongs to the copper-clad plate and makes technical field. The technical problem that in the prior art, the copper-clad plate is likely to rotate and turn over in the transportation process, and further subsequent packaging work is hindered is solved. The limiting feeding component for copper-clad plate production comprises an installation space in an installation frame. The conveying line is installed at the bottom of the installation space and is provided with a feeding end and a discharging end. The mounting plate is slidably mounted at the bottom of the mounting space and located between the conveying line and the mounting frame, and the mounting plate is used for being abutted to the side face of the raw material plate. The buffering closing member is installed on the inner wall of the installation space and is positioned between the installation plate and the installation frame. Compress tightly the top of piece installation mounting bracket to be located the top of transfer chain, compress tightly the piece and be used for keeping away from one side butt of the bottom of mounting bracket with the raw materials board.

Description

Spacing pay-off subassembly of copper-clad plate production

Technical Field

The utility model belongs to the technical field of the copper-clad plate is made, in particular to spacing pay-off subassembly of copper-clad plate production.

Background

The copper-clad plate is a basic material in the electronic industry, is mainly used for processing and manufacturing printed circuit boards, and is widely applied to electronic products such as televisions, radios, computers, mobile communication and the like. The copper-clad plate is manufactured by using paper and glass fiber cloth as base materials, soaking the base materials with resin to manufacture bonding sheets (adhesive tape and adhesive tape), and combining a plurality of bonding sheets.

According to the retrieval, the automatic carrying and weighing conveyor for the copper clad plate material with the application number of CN201910699892.1 comprises a portal frame, a feeding mechanism and a weighing and correcting conveying mechanism, wherein the portal frame stretches across the feeding mechanism and the weighing and correcting conveying mechanism from front to back, a plurality of copper clad plate units which are stacked in a staggered mode are arranged on the feeding mechanism, the copper clad plate units are conveyed to the weighing and correcting conveying mechanism through the feeding mechanism to be weighed and corrected, and the copper clad plate units meeting the set weight requirement are conveyed to an inlet of a packing machine. This application is mutually supported through between tong mechanism and the roller curtain, carries the copper-clad plate unit to the belt of weighing, and the belt of weighing is weighed and is rectified the copper-clad plate unit and carry the copper-clad plate unit to the baling press entry through conveying unit. This application has accomplished separation, transport, the work of weighing, correction and carrying to the baling press entry of piling up the copper-clad plate unit automatically, has not only improved production efficiency and packing quality, has alleviateed workman's intensity of labour moreover, improves the product yield.

The following problems also exist in the prior art: in the conveying process of the copper-clad plate, the copper-clad plate is limited only by the correcting mechanisms on two sides, and the copper-clad plate can rotate and turn over in the conveying process on the weighing belt, so that subsequent packing work is hindered.

SUMMERY OF THE UTILITY MODEL

The utility model provides a spacing pay-off subassembly of copper-clad plate production to solve among the prior art copper-clad plate and probably take place to rotate and overturn in the transportation, and then hinder subsequent packing work.

In order to achieve the above purpose, the utility model discloses a following technical scheme realizes: the limiting feeding component for producing the copper-clad plate comprises an installation frame, a conveying line, an installation plate, a buffering assembly and a pressing assembly, wherein an installation space is formed in the installation frame. The conveying line is arranged at the bottom of the mounting space and is provided with a feeding end and a discharging end. The mounting panel slidable mounting be in installation space's bottom, and be located the transfer chain with between the mounting bracket, the mounting panel be used for with the side butt of raw materials board. The buffering closes the piece and installs on installation space's the inner wall, and be located the mounting panel with between the mounting bracket. Compress tightly to close the installation the top of mounting bracket to be located the top of transfer chain, it is used for keeping away from with the former apron to compress tightly to close the piece one side butt of the bottom of mounting bracket.

Through the structure, the utility model provides a spacing pay-off subassembly of copper-clad plate production can carry on spacingly to the copper-clad plate to prevent that the copper-clad plate from taking place rotation and upset in the transportation. Specifically, place the copper-clad plate and serve at the pan feeding of transfer chain, the transfer chain starts to move in order to drive the copper-clad plate to the direction that is close to the discharge end afterwards, then raw material plate and mounting panel butt to drive the mounting panel to the direction motion of keeping away from the transfer chain, and extrusion buffering closes the piece, and the inboard of mounting panel and installation space respectively with two relative side butts of raw material plate under the effect of buffering closes the piece afterwards, in order to spacing to raw material plate, and not crushing raw material plate. Simultaneously, compress tightly close piece and the former feed plate and keep away from one side butt of the bottom of mounting bracket is in order to prevent that the former feed plate from not overturning in the transportation.

Optionally, the mounting bracket includes a bottom plate and two side plates, the two side plates are vertically installed on the bottom plate, the conveying line is located between the two side plates, and the two side plates and the bottom plate enclose the installation space.

Optionally, the spacing pay-off subassembly of copper-clad plate production still includes the rotating shaft group, and the rotating shaft group rotates to be installed the mounting panel is close to one side of transfer chain for with the side butt of raw materials board.

Optionally, the mounting panel the pivot group and the buffering closes the piece and is two, and all with two curb plate one-to-one, the one end that the buffering closed is installed the curb plate is close to on one side of transfer chain, the mounting panel is installed the buffering closes the piece and is close to one of transfer chain is served, two pivot groups be used for with the relative both sides butt of raw material plate, raw material plate to being close to the direction motion of discharge end is in order to drive two pivot group rotate.

Optionally, the buffering closes the piece and includes guiding axle and pressure spring, seted up on the curb plate with the through-hole that the guiding axle corresponds, the one end of guiding axle is installed on the mounting panel, the other end of guiding axle passes the through-hole is to keeping away from the transfer chain direction extends. The pressure spring is sleeved outside the guide shaft, and two ends of the pressure spring are respectively installed on the mounting plate and the side plates.

Optionally, the hold-down assembly includes a mounting beam, a spring, a square frame, and a roller shaft set. One end of the mounting beam is mounted at one end, far away from the bottom plate, of any one side plate, and the other end of the mounting beam is mounted at one end, far away from the bottom plate, of the other side plate. One end of the spring is installed on one side, close to the mounting rack, of the mounting beam, and the other end of the spring extends towards the direction close to the mounting rack. The square frame is arranged at one end of the two springs close to the mounting frame. The roller shaft group is rotatably installed in the square frame, the roller shaft group and the conveying line are respectively abutted against two opposite surfaces of the raw material plate so as to clamp the raw material plate, and the raw material plate moves towards the direction close to the discharge end so as to drive the roller shaft group to rotate.

Optionally, the pressing assembly further comprises two limiting rods, two limiting holes in one-to-one correspondence with the two limiting rods are formed in one side, close to the bottom plate, of the mounting beam, one ends of the two limiting rods are installed on one side, away from the bottom plate, of the square frame, the other ends of the two limiting rods penetrate through the two limiting holes respectively and extend towards the direction away from the bottom plate, the number of the springs is two, and the two springs are in one-to-one correspondence with the two limiting rods and sleeved outside the two limiting rods.

Optionally, the conveying line includes a frame and rolling shaft sets, the frame is installed on the bottom plate and located between the two rolling shaft sets, and the discharging end and the feeding end are located on the frame. The rolling shaft group is rotatably arranged at the top end of the frame and rotates to drive the raw material plate to move towards the direction close to the discharge end.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below, it is obvious that the drawings in the following description are only some embodiments of the present invention, and for those skilled in the art, other drawings can be obtained according to these drawings without creative efforts.

FIG. 1 is a schematic structural view of a limiting feeding component for copper-clad plate production provided by the embodiment of the present invention;

FIG. 2 is another schematic structural diagram of a limiting feeding assembly for copper-clad plate production provided by the embodiment of the present invention;

fig. 3 is a schematic structural diagram of a conveying line according to an embodiment of the present invention;

fig. 4 is an assembly schematic view of a buffering assembly provided by the embodiment of the present invention;

FIG. 5 is an enlarged view taken at A in FIG. 4;

fig. 6 is a schematic structural diagram of a pressing assembly provided by an embodiment of the present invention.

In the figure: 1-a mounting frame; 11-a base plate; 12-side plates; 121-through holes; 2-conveying line; 21-a frame; 22-rolling axis group; 23-a drive motor; 3, mounting a plate; 4-rotating shaft group; 41-rotating the sleeve; 5-a buffer assembly; 51-a guide shaft; 52-pressure spring; 6-pressing the assembly; 61-mounting the beam; 611-a limiting hole; 62-a spring; 63-block; 64-roller group; 641-a roller; 65-a limiting rod; 7-raw material plate.

Detailed Description

Embodiments of the present application are described in detail below with reference to the accompanying drawings.

In the description of the present application, it is to be understood that the terms "center", "upper", "lower", "front", "rear", "left", "right", "vertical", "horizontal", "top", "bottom", "inner", "outer", and the like indicate orientations or positional relationships based on those shown in the drawings, merely for convenience of description and simplicity of description, and do not indicate or imply that the devices or elements referred to must have a particular orientation, be constructed in a particular orientation, and be operated, and thus, are not to be construed as limiting the present application.

The terms "first", "second" and "first" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance or implicitly indicating the number of technical features indicated. Thus, a feature defined as "first" or "second" may explicitly or implicitly include one or more of that feature. In the description of the present application, "a plurality" means two or more unless otherwise specified.

In the description of the present application, it is to be noted that, unless otherwise explicitly specified or limited, the terms "mounted," "connected," and "connected" are to be construed broadly, e.g., as meaning either a fixed connection, a removable connection, or an integral connection; can be mechanically or electrically connected; they may be connected directly or indirectly through intervening media, or they may be interconnected between two elements. The specific meaning of the above terms in the present application can be understood in a specific case by those of ordinary skill in the art.

Examples

The following problems also exist in the prior art: in the conveying process of the copper-clad plate, the copper-clad plate is limited only by the correcting mechanisms on two sides, and the copper-clad plate is likely to rotate and turn over in the conveying process on the weighing belt, so that the subsequent packing work is hindered.

In order to solve the above technical problem, the present embodiment provides a limiting feeding component for copper-clad plate production, which includes an installation frame 1, a conveying line 2, an installation plate 3, a buffering assembly 5 and a pressing assembly 6 as shown in fig. 1 and fig. 2. The mounting frame 1 has a mounting space therein. The conveying line 2 is installed at the bottom of the installation space and is provided with a feeding end and a discharging end. The mounting plate 3 is slidably mounted at the bottom of the mounting space and is positioned between the conveying line 2 and the mounting frame 1, and the mounting plate 3 is used for being abutted against the side face of the raw material plate 7. The buffer 5 is installed on the inner wall of the installation space and between the installation plate 3 and the installation frame 1. The top of closing member 6 installation mounting bracket 1 compresses tightly to be located the top of transfer chain 2, and it is used for keeping away from the one side butt of the bottom of mounting bracket 1 with former flitch 7 to compress tightly closing member 6.

Through the structure, the limiting feeding assembly for producing the copper-clad plate can limit the copper-clad plate so as to prevent the copper-clad plate from rotating and overturning in the transportation process. Specifically, place the copper-clad plate on the pan feeding of transfer chain 2 is served, transfer chain 2 starts afterwards to move to the direction that is close to the discharge end in order to drive the copper-clad plate, then former feed plate 7 and 3 butts of mounting panel, move to the direction of keeping away from transfer chain 2 in order to drive mounting panel 3, and extrusion buffering closes piece 5, later under the effect that buffering closes piece 5 mounting panel 3 with the inboard of installation space respectively with two relative side butts of former feed plate 7, in order to 7 spacingly to former feed plate, and do not crush former feed plate 7. Meanwhile, the pressing part 6 abuts against one side of the raw material plate 7, which is far away from the bottom of the mounting frame 1, so that the raw material plate 7 is prevented from turning over in the transportation process.

Based on the basis of the complaint, the conveying line 2, the mounting plate 3, the buffering assembly 5 and the pressing assembly 6 are convenient to mount. As shown in fig. 2, the mounting rack 1 includes a bottom plate 11 and two side plates 12, the two side plates 12 are vertically installed on the bottom plate 11, the conveying line 2 is located between the two side plates 12, and the two side plates 12 and the bottom plate 11 enclose to form an installation space.

Based on the basis of telling, in order to make former feed plate 7 and mounting panel 3 butt can drive mounting panel 3 to the direction motion of keeping away from transfer chain 2 and extrude buffering closes piece 5, and make former feed plate 7 bear littleer frictional force in the transportation, spacing pay-off subassembly of copper-clad plate production as shown in fig. 4 still includes rotating shaft group 4, rotating shaft group 4 comprises a plurality of rotating sleeve 41, rotating sleeve 41's quantity and transfer chain 2's length are directly proportional, transfer chain 2 is longer, rotating sleeve 41 is more. A plurality of rotating sleeves 41 are rotatably laid on the side of the mounting plate 3 close to the conveyor line 2 and are used for abutting against the side face of the raw material plate 7. Specifically, raw material plate 7 and the butt of rotating sleeve 41, rotate sleeve 41 and rotate in order to drive, and drive and rotate sleeve 41 and to keeping away from 2 direction movements of transfer chain, in order to drive mounting panel 3 and to keeping away from 2 direction movements of transfer chain, and in the transportation of raw material plate 7, raw material plate 7 is far less than with the area of rotating sleeve 41, the area of raw material plate 7 direct and the contact of mounting panel 3, and for rolling friction, consequently reduced the frictional force that raw material plate 7 bore in the transportation.

In order to make the forces to which the raw material sheet 7 is subjected during transportation more uniform, and in order to further reduce the frictional forces to which the raw material sheet 7 is subjected. As shown in fig. 2, the mounting plate 3, the rotating shaft group 4 and the buffering assembly 5 are two, and are respectively in one-to-one correspondence with the two side plates 12, one end of the buffering assembly 5 is mounted on one side of the side plate 12 close to the conveying line 2, the mounting plate 3 is mounted on one end of the buffering assembly 5 close to the conveying line 2, and the two rotating shaft groups 4 are used for being abutted to two opposite sides of the raw material plate 7. Specifically, the two sets of rotating shafts 4 rotate along with the movement of the raw material plate 7 toward the direction close to the discharge end, so as to reduce the friction force to which the raw material plate 7 is subjected during transportation.

Based on the basis, in order to enable the buffering assembly 5 to play a role in buffering when the mounting plate 3 moves away from the conveying line 2, thrust is applied to the mounting plate 3 to drive the rolling cylinder on the mounting plate 3 to abut against the mounting plate. As shown in fig. 5, the buffer assembly 5 includes a guide shaft 51 and a pressure spring 52, a through hole 121 corresponding to the guide shaft 51 is formed in the side plate 12, one end of the guide shaft 51 is mounted on the mounting plate 3, and the other end of the guide shaft 51 passes through the through hole 121 and extends in a direction away from the conveyor line 2. The compression spring 52 is sleeved outside the guide shaft 51, and two ends of the compression spring 52 are respectively installed on the installation plate 3 and the side plate 12. Specifically, when carrying raw material plate 7, raw material plate 7 and rotation sleeve 41 butt to drive rotation sleeve 41 and rotate, and drive rotation sleeve 41 and to keeping away from 2 direction movements of transfer chain, and to drive mounting panel 3 and to keeping away from 2 direction movements of transfer chain, and then make pressure spring 52 compressed, pressure spring 52 applys external force to mounting panel 3 simultaneously and rotates sleeve 41 and raw material plate 7 and be close to the one side butt of this mounting panel 3 in order to promote, and then carries on spacingly to raw material plate 7. Preferably, the number of the guide shafts 51 is four, the number of the compression springs 52 is four, the number of the through holes 121 is four, the four guide shafts 51, the four compression springs 52 and the four through holes 121 are in one-to-one correspondence, and the four guide shafts 51 are respectively close to four corners of the mounting plate 3.

Based on the above, in order to make the pressing member 6 capable of restricting the raw material plate 7 from turning during transportation, the pressing member 6 includes a mounting beam 61, a spring 62, a frame 63, and a roller set 64 as shown in fig. 6. One end of the mounting beam 61 is mounted at one end of any one of the side plates 12 far away from the bottom plate 11, and the other end of the mounting beam 61 is mounted at one end of the other side plate 12 far away from the bottom plate 11. One end of the spring 62 is mounted on the mounting beam 61 on the side close to the mounting bracket 1, and the other end of the spring 62 extends in the direction close to the mounting bracket 1. The block 63 is mounted at one end of the two springs 62 near the mounting 1. The roller set 64 is composed of a plurality of rollers 641, the number of rollers 641 is proportional to the length of the conveyor line 2, and the longer the conveyor line 2 is, the more rollers 641 are. The rollers are rotatably laid inside the frame 63, and the rollers 641 and the conveyor line 2 are respectively brought into contact with the opposite surfaces of the raw material sheet 7. Specifically, when the raw material plate 7 is conveyed, one side of the raw material plate 7, which is far away from the conveying line 2, abuts against the roller 641 to drive the square frame 63 to rise, meanwhile, the spring 62 is compressed to enable the tensile force of the spring 62 on the square frame 63 to be smaller than the gravity of the square frame 63 and the roller group 64, the roller 641 presses the raw material plate 7 under the action of a part of gravity larger than the tensile force of the spring 62, so that the raw material plate 7 cannot turn over in the conveying process, meanwhile, due to the fact that the thickness of the raw material plate 7 is smaller, the spring 62 contracts less, the tensile force of the spring 62 is smaller, the part of gravity larger than the tensile force of the spring 62 is also smaller, the raw material plate 7 cannot be crushed, the roller 641 is driven to rotate when the raw material plate 7 moves towards the direction close to the discharge end, and the friction force applied to the raw material plate 7 is reduced.

In order to enable the compressing assembly 6 to be better limited in the ascending and descending processes, as shown in fig. 6, the compressing assembly 6 further includes two limiting rods 65, two limiting holes 611 corresponding to the two limiting rods 65 are formed in one side, close to the bottom plate 11, of the mounting beam 61, one end of each of the two limiting rods 65 is mounted on one side, away from the bottom plate 11, of the frame 63, the other end of each of the two limiting rods 65 penetrates through the two limiting holes 611 and extends in the direction away from the bottom plate 11, the number of the springs 62 is two, and the two springs 62 correspond to the two limiting rods 65 one to one and are sleeved outside the two limiting rods 65.

Based on the above, transfer chain 2 is the roller section of thick bamboo transfer chain 2 of last temper horse automation equipment limited company production, and it is prior art from taking driving motor 23, and as shown in fig. 3 transfer chain 2 includes frame 21 and rolling axle group 22, and frame 21 installs on bottom plate 11 and is located between two rotating shaft group 4, and discharge end and pan feeding end are located frame 21. The rolling shaft group 22 is rotatably installed at the top end of the frame 21, and the rolling shaft group 22 rotates to drive the raw material plate 7 to move towards the direction close to the discharging end. Specifically, the driving motor 23 rotates to drive the rolling shaft set 22 to rotate, and further drive the raw material plate 7 to move towards the direction close to the discharging end.

In summary, in the process of transporting the raw material plate 7, firstly, the copper-clad plate is placed on the feeding end of the conveying line 2, and the driving motor 23 rotates to drive the rolling shaft group 22 to rotate, so as to drive the raw material plate 7 to move towards the direction close to the discharging end. Then raw material plate 7 and the rotating sleeve 41 butt of both sides to the rotating sleeve 41 that drives both sides rotates, and drives the rotating sleeve 41 of both sides and move to keeping away from transfer chain 2 direction respectively, moves to keeping away from transfer chain 2 direction respectively with the mounting panel 3 that drives both sides. And then make eight pressure springs 52 of both sides all compressed, eight pressure springs 52 simultaneously, four fours are a set of exerting external force in order to promote the relative both sides butt of the rotating sleeve 41 and the raw materials board 7 of both sides in order to spacing to raw materials board 7, and do not crush raw materials board 7 to the mounting panel 3 of homonymy respectively. Meanwhile, the side of the raw material plate 7 away from the conveyor line 2 abuts against the roller 641 to lift the frame 63, the spring 62 is compressed to make the pulling force of the spring 62 on the frame 63 smaller than the gravity of the frame 63 and the roller group 64, and the roller 641 presses the raw material plate 7 under the action of the gravity of the spring 62, so that the raw material plate 7 cannot turn over during transportation. Therefore, the limiting feeding assembly can limit the copper-clad plate so as to prevent the copper-clad plate from rotating and overturning in the transportation process.

The above description is only for the specific embodiments of the present invention, but the protection scope of the present invention is not limited thereto, and any person skilled in the art can easily think of the changes or substitutions within the technical scope of the present invention, and all should be covered within the protection scope of the present invention. Therefore, the protection scope of the present invention shall be subject to the protection scope of the claims.

Claims (8)

1. Spacing pay-off subassembly of copper-clad plate production, its characterized in that includes:

the mounting frame is internally provided with a mounting space;

the conveying line is arranged at the bottom of the installation space and is provided with a feeding end and a discharging end;

the mounting plate is slidably mounted at the bottom of the mounting space and is positioned between the conveying line and the mounting frame, and the mounting plate is used for abutting against the side face of the raw material plate;

the buffer assembly is arranged on the inner wall of the installation space and is positioned between the installation plate and the installation frame;

and the pressing assembly is mounted at the top of the mounting frame and positioned above the conveying line, and the pressing assembly is used for being abutted against one side of the bottom of the mounting frame away from the raw material plate.

2. The spacing pay-off subassembly of copper-clad plate production of claim 1, characterized in that, the mounting bracket includes:

a base plate;

the two side plates are vertically installed on the bottom plate, the conveying line is located between the two side plates, and the two side plates and the bottom plate are enclosed to form the installation space.

3. The copper-clad plate production limiting and feeding assembly of claim 2, further comprising:

and the rotating shaft group is rotatably installed on one side, close to the conveying line, of the mounting plate and is used for being abutted to the side face of the raw material plate.

4. The copper-clad plate production limiting feeding assembly according to claim 3, wherein the number of the mounting plate, the rotating shaft sets and the buffering assembly is two, the two mounting plates are in one-to-one correspondence with the two side plates, one end of the buffering assembly is mounted on one side of the side plate close to the conveying line, the mounting plate is mounted on one end of the buffering assembly close to the conveying line, the two rotating shaft sets are used for being abutted to two opposite sides of a raw material plate, and the raw material plate moves towards the direction close to the discharge end to drive the two rotating shaft sets to rotate.

5. The copper-clad plate production limiting and feeding assembly of claim 4, wherein the buffering assembly comprises:

the side plate is provided with a through hole corresponding to the guide shaft, one end of the guide shaft is installed on the installation plate, and the other end of the guide shaft penetrates through the through hole and extends in the direction far away from the conveying line;

the pressure spring is sleeved outside the guide shaft, and two ends of the pressure spring are respectively installed on the mounting plate and the side plate.

6. The spacing pay-off subassembly of copper-clad plate production of claim 2, characterized in that, the pressure close piece includes:

one end of the mounting beam is mounted at one end of any one side plate far away from the bottom plate, and the other end of the mounting beam is mounted at one end of the other side plate far away from the bottom plate;

one end of the spring is installed on one side, close to the mounting rack, of the mounting beam, and the other end of the spring extends towards the direction close to the mounting rack;

the square frame is arranged at one end of the two springs close to the mounting frame;

the roller shaft group is rotatably installed inside the square frame, the roller shaft group is abutted to two opposite faces of the raw material plate by the conveying line respectively so as to clamp the raw material plate, and the raw material plate moves towards the direction close to the discharge end so as to drive the roller shaft group to rotate.

7. The spacing pay-off subassembly of copper-clad plate production of claim 6, characterized in that, the pressure close piece still includes:

two gag lever posts, the installation roof beam is close to one side of bottom plate seted up with two spacing holes of two gag lever posts one-to-one, the one end of two gag lever posts is installed the square frame is kept away from on one side of bottom plate, the other end of two gag lever posts passes respectively two spacing holes to keeping away from the direction of bottom plate extends, the spring is two, two springs with two gag lever posts one-to-one, and the cover is established outside two gag lever posts.

8. The copper-clad plate production limiting feeding assembly according to claim 4, wherein the conveying line comprises:

the frame is arranged on the bottom plate and positioned between the two rotating shaft groups, and the discharging end and the feeding end are positioned on the frame;

and the rolling shaft group is rotatably arranged at the top end of the frame and rotates to drive the raw material plate to move towards the direction close to the discharge end.

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