CN214517230U - Steel mesh feeding mechanism - Google Patents

Abstract

The utility model belongs to the technical field of material area material feeding unit, a steel mesh feeding mechanism is disclosed, include: the telescopic clamping device comprises a base plate, a telescopic cylinder, a limiting piece and two clamping components; in a first horizontal direction, the substrate is provided with a feeding end and a discharging end; the two clamping assemblies are respectively positioned at the feeding end and the discharging end; the clamping assemblies are arranged above the base plate, each clamping assembly comprises an upper clamping plate, a lower clamping plate and an opening and closing driving unit for driving the lower clamping plate and the upper clamping plate to open and close, the two lower clamping plates are connected with the base plate in a sliding mode, a connecting piece is arranged between the two lower clamping plates, and two ends of the connecting piece are connected to the two lower clamping plates respectively; the limiting part is connected to the substrate, one of the limiting part and the connecting part is connected with the limiting part, the other one is provided with a limiting groove corresponding to the limiting part, and the limiting groove is formed along the first horizontal direction; one of the cylinder body of the telescopic cylinder and the piston rod of the telescopic cylinder is connected with any one lower clamping plate, and the other is connected with the base plate.

Description

Steel mesh feeding mechanism

Technical Field

The utility model belongs to the technical field of material area material feeding unit, concretely relates to steel mesh feeding mechanism.

Background

In the production process, part spare part integrated into one piece is on the material area, and the storage and the transport of being convenient for, during the equipment, with spare part follow material area on the die cutting off can. When cutting, the material belt is fed into a cutting die through a steel mesh feeding mechanism; among the prior art, steel mesh feeding mechanism arranges in cutting die's discharge gate or pan feeding mouth department, and the pay-off in-process easily leads to the material area to arch up or undercut because of there are reasons such as pay-off resistance in material area soft or hard difference and blanking die, and then leads to the material area dislocation, arouses blanking die card material.

SUMMERY OF THE UTILITY MODEL

In order to solve the problems existing in the prior art, the utility model aims to provide a steel mesh feeding mechanism.

The utility model discloses the technical scheme who adopts does:

steel mesh feeding mechanism includes: the telescopic mechanism comprises a base plate, a telescopic cylinder, a limiting piece and two clamping assemblies arranged at intervals;

in a first horizontal direction, the substrate is provided with a feeding end and a discharging end; the two clamping assemblies are respectively positioned at the feeding end and the discharging end; the clamping assemblies are arranged above the base plate and are arranged in a sliding mode along the first horizontal direction, each clamping assembly comprises an upper clamping plate, a lower clamping plate and an opening and closing driving unit for driving the lower clamping plate and the upper clamping plate to open and close, the two lower clamping plates are connected with the base plate in a sliding mode, a connecting piece is arranged between the two lower clamping plates, and two ends of the connecting piece are connected to the two lower clamping plates respectively;

the limiting part is connected to the substrate, one of the limiting part and the connecting part is connected with the limiting part, the other one of the limiting part and the connecting part is provided with a limiting groove corresponding to the limiting part, and the limiting groove is formed along the first horizontal direction;

one of the cylinder body of the telescopic cylinder and the piston rod of the telescopic cylinder is connected with any one of the lower clamping plates, and the other one is connected with the base plate.

As a further alternative to the steel mesh feeding mechanism, each of the clamping assemblies further comprises: the flow channel plate and the cover plate are arranged above the flow channel plate;

a guide cavity for a material belt to pass through is formed between the runner plate and the cover plate, the runner plate is provided with a first avoidance hole for avoiding the lower clamping plate, and the first avoidance hole is communicated with the guide cavity;

the cover plate is provided with a second avoiding hole for avoiding the upper clamping plate, and the second avoiding hole is communicated with the guide cavity.

As a further alternative of the steel mesh feeding mechanism, the steel mesh feeding mechanism further comprises: the guide pipe is hollow and two ends of the guide pipe are opened;

an opening at one end of the guide pipe is in butt joint with the guide cavity of any one of the clamping assemblies, and the other end of the guide pipe extends downwards and then extends towards the other clamping assembly along the first horizontal direction.

As a further alternative of the steel mesh feeding mechanism, the steel mesh feeding mechanism further comprises: a material belt positioning component; the material belt positioning component comprises a connecting block, a positioning needle and a first spring; the connecting block is connected to the cover plate; the positioning needle is connected to the connecting block in a vertical sliding manner; the first spring is arranged between the connecting block and the positioning needle and used for driving the positioning needle to move upwards; the cover plate is provided with a third avoidance hole for avoiding the positioning pin.

As a further alternative of the steel mesh feeding mechanism, a boss is convexly arranged at the upper part of the positioning needle; the first spring is sleeved outside the positioning needle, and two ends of the first spring respectively abut against the connecting block and the boss.

As a further alternative of the steel mesh feeding mechanism, the clamping assembly at the feeding end further comprises: two material pressing components arranged in parallel along a second horizontal direction; the second horizontal direction is perpendicular to the first horizontal direction;

each material pressing component comprises a pressing block, a second spring and a spring mounting block;

the spring mounting block is connected to the cover plate;

the pressing block is connected to the spring mounting block in a sliding mode in the vertical direction;

the second spring is arranged between the spring mounting block and the pressing block and used for driving the pressing block to move downwards;

the cover plate is provided with a fourth avoidance hole for avoiding the pressing block.

As a further alternative to the steel mesh feeding mechanism, the spring mounting block extends with an extension in a horizontal direction; the extension part is provided with a vertically penetrating matching hole which is matched with the pressing block; the lower part of the pressing block is provided with a step; two ends of the second spring respectively abut against the step and the extending part.

As a further alternative of the steel mesh feeding mechanism, the pressing block positioned above the extension part is rotatably connected with a rotating rod; when the rotating rod rotates to a first state, the pressing block loosens the material belt in the guide cavity; when the dwang rotated to the second state, the briquetting compressed tightly the material area in the direction cavity.

As a further alternative of the steel mesh feeding mechanism, the discharge end of the substrate is connected with a bracket; the bracket is connected with a sensor; the sensing end of the sensor faces upwards.

As a further alternative of the steel mesh feeding mechanism, a linear rolling guide rail is arranged between each lower clamping plate and the base plate; the linear rolling guide rail is arranged along a first horizontal direction.

The utility model has the advantages that:

during the use, blanking mould is located between two clamping components, and the drive unit that opens and shuts through drive punch holder and lower plate to loosen or press from both sides tight material area, the telescopic cylinder drive two clamping components along first horizontal direction reciprocating sliding, accomplish the pay-off action in material area. Compared with the prior art, the utility model discloses a pan feeding end and the discharge end at the base plate respectively close and set up a clamping component to slide along first horizontal direction simultaneously through two clamping components of telescopic cylinder drive, at the pay-off in-process, ensure that the length in material area between two clamping components is unchangeable, thereby avoid the material area between two clamping components to upwards arch or undercut, and then avoid the card material.

Drawings

Fig. 1 is a schematic structural view of a first embodiment of a steel mesh feeding mechanism according to the present invention.

Fig. 2 is a schematic structural view of a second embodiment of the steel mesh feeding mechanism of the present invention.

Fig. 3 is a schematic structural view of a third embodiment of the steel mesh feeding mechanism of the present invention.

Fig. 4 is a schematic structural view of a cover plate and a runner plate in the steel net feeding mechanism shown in fig. 1 or 3.

Fig. 5 is a structural schematic view of the pressing assembly in the steel net feeding mechanism shown in fig. 1 or 3 in a first state.

Fig. 6 is a structural schematic view of the pressing assembly in the steel net feeding mechanism shown in fig. 1 or 3 in a second state.

Fig. 7 is an exploded view of the tape positioning assembly in the steel net feeding mechanism shown in fig. 1 or 3.

In the figure: 10-a substrate; 20-a telescopic cylinder; 30-a limit piece; 31-a limiting groove; 40-a clamping assembly; 41-upper splint; 42-lower splint; 43-an opening and closing drive unit; 44-linear rolling guide; 45-flow channel plate; 451-first avoidance hole; 46-a cover plate; 461-second avoiding hole; 462-a third avoidance hole; 463-fourth relief hole; 47-a guide cavity; 48-a connector; 481-stop block; 50-material belt; 51-a positioning hole; 60-a guide tube; 70-a material belt positioning component; 71-connecting blocks; 72-a positioning needle; 721-a boss; 73-a first spring; 74-a clamp spring; 80-a material pressing component; 81-briquetting; 811-step; 82-a second spring; 83-spring mounting block; 831-an extension; 84-rotating rods; 90-a scaffold; 100-a sensor; 110-blanking die.

Detailed Description

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the present invention will be briefly described below with reference to the accompanying drawings and the description of the embodiments or the prior art, and it is obvious that the following description of the structure of the accompanying drawings is only some embodiments of the present invention, and for those skilled in the art, other drawings can be obtained according to the drawings without any inventive work.

The technical solution provided by the present invention will be described in detail by way of embodiments with reference to the accompanying drawings. It should be noted that the description of the embodiments is provided to help understanding of the present invention, but the present invention is not limited thereto.

In some instances, some embodiments are not described or not in detail, as they are conventional or customary in the art.

The numbering of the components as such, e.g., "first", "second", etc., is used herein only to distinguish the objects as described, and does not have any sequential or technical meaning. The terms "connected" and "coupled" when used in this application, encompass both direct and indirect connections (and couplings) where appropriate and where not necessary contradictory.

The terms "horizontal direction", "up", "down" and the like are all based on the orientation of the steel net feeding mechanism in the normal use state, i.e. the orientation shown in fig. 1.

As shown in fig. 1, the steel net feeding mechanism of the present embodiment includes: the telescopic mechanism comprises a base plate 10, a telescopic cylinder 20, a limiting piece 30 and two clamping assemblies 40 which are arranged at intervals;

in a first horizontal direction, the substrate 10 has a feeding end and a discharging end; the two clamping assemblies 40 are respectively positioned at the feeding end and the discharging end; the clamping assemblies 40 are arranged above the base plate 10, the clamping assemblies 40 are arranged in a sliding mode along a first horizontal direction, each clamping assembly 40 comprises an upper clamping plate 41, a lower clamping plate 42 and an opening and closing driving unit 43 for driving the lower clamping plate 42 and the upper clamping plate 41 to open and close, the two lower clamping plates 42 are connected with the base plate 10 in a sliding mode, a connecting piece 48 is arranged between the two lower clamping plates 42, and two ends of the connecting piece 48 are connected to the two lower clamping plates 42 respectively;

the limiting member 30 is connected to the substrate 10, one of the limiting member 30 and the connecting member 48 is connected to the limiting member 481, the other is provided with a limiting groove 31 corresponding to the limiting member 481, and the limiting groove 31 is formed along the first horizontal direction;

one of the cylinder body of the telescopic cylinder 20 and the piston rod of the telescopic cylinder 20 is connected to either one of the lower clamp plates 42, and the other is connected to the base plate 10.

In use, the blanking die 110 is located between the two clamping assemblies 40, as shown in figure 1.

The opening and closing driving unit 43 can be realized by adopting the prior art such as a spiral clamping mechanism, a gear rack mechanism, a clamping jaw cylinder and the like. In one embodiment, as shown in fig. 1, the opening and closing driving unit 43 is implemented by using a cylinder with a guide rod, specifically, a cylinder body of the cylinder with the guide rod is connected to the lower clamping plate 42, and a piston rod of the cylinder with the guide rod is connected to the upper clamping plate 41.

In one embodiment, as shown in fig. 1, 2 and 3, each clamping assembly 40 includes two upper clamping plates 41 and two lower clamping plates 42, with one upper clamping plate 41 corresponding to one lower clamping plate 42; the two pairs of upper clamping plates 41 and the two pairs of lower clamping plates 42 are respectively arranged along the second horizontal direction and respectively clamp two sides of the material belt 50 along the width direction, and in the feeding process, the material belt 50 is stressed in a balanced manner and is not easy to skew, and a cylinder with a guide rod is prevented from bearing large bending moment.

The two ends of the connecting member 48 are connected to the two lower clamping plates 42, respectively, to ensure that the two clamping assemblies 40 move simultaneously. In one embodiment, as shown in fig. 1, a limiting block 481 is integrally formed at the middle of the connecting member 48, a limiting groove 31 is formed on the top surface of the limiting member 30 along the first horizontal direction, and the size of the limiting groove 31 along the first horizontal direction and the size of the limiting block 481 along the first horizontal direction determine the feeding step. Obviously, the stopper 481 may be integrally formed on the stopper 30, and the stopper groove 31 may be formed on the bottom surface of the connecting member 48.

The connection between the lower clamping plate 42 and the base plate 10 can be achieved by the prior art, such as a slider-runner structure, and in one embodiment, as shown in fig. 1, a linear rolling guide 44 is disposed between each lower clamping plate 42 and the base plate 10; the linear rolling guide 44 is disposed in the first horizontal direction; in one embodiment, the rails of both linear rolling guides 44 are connected to the base plate 10; the slide blocks of the two linear rolling guide rails 44 are respectively connected with the two lower clamping plates 42; in another embodiment, the rails of the two linear rolling guides 44 are connected to the two lower clamping plates 42, respectively; the slides of both linear rolling guides 44 are connected to the base plate 10.

The telescopic cylinder 20 can be implemented by a cylinder, an electric cylinder, etc. in one embodiment, as shown in fig. 1, the telescopic cylinder 20 is implemented by a rectangular cylinder, specifically, a cylinder body of the rectangular cylinder is connected to the base plate 10, and a piston rod of the rectangular cylinder is connected to any one of the lower clamping plates 42; in another embodiment, a cylinder of a rectangular cylinder is connected to either lower clamp plate 42, and a piston rod of the rectangular cylinder is connected to base plate 10.

In one embodiment, as shown in fig. 2 and 3, each clamping assembly 40 may further include: a flow channel plate 45 and a cover plate 46 disposed above the flow channel plate 45;

as shown in fig. 4, a guide cavity 47 for the material tape 50 to pass through is formed between the flow channel plate 45 and the cover plate 46, the flow channel plate 45 is provided with a first avoidance hole 451 avoiding the lower clamp plate 42, and the first avoidance hole 451 is communicated with the guide cavity 47;

the cover plate 46 is provided with a second avoiding hole 461 avoiding the upper clamping plate 41, and the second avoiding hole 461 leads to the guide cavity 47.

The guide cavity 47 is used for guiding the tape 50, on one hand, ensuring that the tape 50 is aligned with the two pairs of upper clamping plates 41 and lower clamping plates 42 along the two sides of the width direction; on the other hand, during feeding, the strip of material 50 is prevented from deflecting.

A through groove can be formed on the top surface of the runner plate 45 along the first horizontal direction to form a guide cavity 47; a through groove can be formed on the bottom surface of the cover plate 46 along the first horizontal direction to form a guide cavity 47; through slots may also be formed in both the top surface of the flow field plate 45 and the bottom surface of the cover plate 46 along the first horizontal direction to form a guide cavity 47.

In one embodiment, as shown in fig. 2, the present steel net feeding mechanism may further include: a hollow guide tube 60 with both ends open;

one end of the guide tube 60 is open to interface with the guide cavity 47 of either clamping assembly 40, and the other end extends downwardly and then in a first horizontal direction toward the other clamping assembly 40.

The tape 50 is placed in the guide tube 60 to prevent the soft tape 50 from winding other components; on the other hand, the feeding and discharging of the material belt 50 are both located on the same side of the substrate 10, which is convenient for manual operation.

In one embodiment, as shown in fig. 2 and 3, the present steel net feeding mechanism may further include: a tape positioning assembly 70; as shown in fig. 7, the tape positioning assembly includes a connecting block 71, a positioning pin 72, and a first spring 73; the connecting block 71 is connected to the cover plate 46; the positioning needle 72 is vertically and slidably connected to the connecting block 71; a first spring 73 is arranged between the connecting block 71 and the positioning pin 72, and the first spring 73 is used for driving the positioning pin 72 to move upwards; the cover plate 46 is opened with a third escape hole 462 for escaping the pilot pin 72.

Through setting up material area locating component, wearing the material in-process, the manual work presses down pilot pin 72, inserts pilot pin 72 and has the material area 50 of locating hole 51 to can confirm whether material area 50 is located the correct position, the manual operation of being convenient for. After confirmation, the positioning needle 72 is loosened, the first spring 73 drives the positioning needle 72 to leave the positioning hole 51 of the material belt 50, and interference of the positioning needle 72 in feeding action due to manual forgetting to take out the positioning needle 72 from the positioning hole 51 is avoided, so that the purpose of fool proofing is achieved.

In one embodiment, the first spring 73 is a compression spring, and as shown in fig. 7, a boss 721 is protruded on the upper portion of the positioning pin 72; the first spring 73 is sleeved outside the positioning pin 72, and two ends of the first spring 73 respectively abut against the connecting block 71 and the boss 721. In one embodiment, as shown in fig. 7, a snap spring 74 is connected to the lower portion of the positioning pin 72 to prevent the positioning pin 72 from flying out of the connecting block 71 under the elastic force of the first spring 73 due to manual release too quickly.

In one embodiment, as shown in fig. 2 and 3, the clamping assembly 40 at the feed end may further include: two pressing assemblies 80 arranged in parallel along a second horizontal direction; the second horizontal direction is vertical to the first horizontal direction; as shown in figures 5 and 6 of the drawings,

each pressing assembly 80 comprises a pressing block 81, a second spring 82 and a spring mounting block 83;

the spring mounting block 83 is connected to the cover plate 46;

the pressing block 81 is vertically slidably connected to the spring mounting block 83;

the second spring 82 is arranged between the spring mounting block 83 and the pressing block 81, and the second spring 82 is used for driving the pressing block 81 to move downwards;

the cover plate 46 is provided with a fourth avoidance hole 463 for avoiding the pressing block 81.

The pressing block 81 is used for pressing the material belt 50, so that the running resistance of the material belt 50 is increased, and the problem that the material belt 50 is stacked due to excessive inertia release caused by the fact that the feeding speed is too high is avoided.

Through setting up two symmetrical material pressing assemblies 80, make material area 50 atress balanced, avoid the material area 50 crooked.

In one embodiment, the second spring 82 is a compression spring, and as shown in fig. 5 and 6, the spring mounting block 83 is extended with an extension portion 831 in a horizontal direction; the extending portion 831 is provided with a vertically penetrating matching hole which is matched with the pressing block 81; the lower part of the pressing block 81 is provided with a step 811; both ends of the second spring 82 respectively abut against the step 811 and the extension 831.

The pressing block 81 located above the extending portion 831 is rotatably connected with a rotating rod 84; when the rotating rod 84 rotates to the first state, the pressing block 81 loosens the material belt 50 in the guide cavity 47; when the rotating rod 84 rotates to the second state, the pressing block 81 presses the material belt 50 in the guide cavity 47. In one embodiment, as shown in fig. 5, the rotating rod 84 is rectangular, and when the rotating rod 84 rotates to the first state, the rotating rod 84 is vertically arranged, and at this time, the pressing block 81 is located at the upper part to loosen the material belt; as shown in fig. 6, when the rotating rod 84 rotates to the second state, the rotating rod 84 is horizontally disposed, and at this time, the pressing block 81 is located at the lower portion to press the material tape.

In one embodiment, as shown in fig. 1 and 2, a support 90 is attached to the discharge end of the substrate 10; the bracket 90 is connected with a sensor 100; the sensing end of the sensor 100 is directed upward. By providing the sensor 100, the presence or absence of the tape 50 and the movement of the tape 50 can be sensed. The sensor 100 may be implemented using existing technologies such as proximity sensors 100.

The present invention is not limited to the above-mentioned optional embodiments, and any other products in various forms can be obtained by anyone under the teaching of the present invention, and any changes in the shape or structure thereof, all the technical solutions falling within the scope of the present invention, are within the protection scope of the present invention.

Claims (10)

1. Steel mesh feeding mechanism, its characterized in that includes: the telescopic mechanism comprises a base plate (10), a telescopic cylinder (20), a limiting piece (30) and two clamping assemblies (40) arranged at intervals;

in a first horizontal direction, the base plate (10) has a feed end and a discharge end; the two clamping assemblies (40) are respectively positioned at the feeding end and the discharging end; the clamping assemblies (40) are arranged above the base plate (10), the clamping assemblies (40) are arranged in a sliding mode along the first horizontal direction, each clamping assembly (40) comprises an upper clamping plate (41), a lower clamping plate (42) and an opening and closing driving unit (43) for driving the lower clamping plate (42) and the upper clamping plate (41) to open and close, the two lower clamping plates (42) are connected with the base plate (10) in a sliding mode, a connecting piece (48) is arranged between the two lower clamping plates (42), and two ends of the connecting piece (48) are connected to the two lower clamping plates (42) respectively;

the limiting piece (30) is connected to the substrate (10), one of the limiting piece (30) and the connecting piece (48) is connected with the limiting piece, the other one is provided with a limiting groove corresponding to the limiting piece, and the limiting groove is formed along the first horizontal direction;

one of the cylinder body of the telescopic cylinder (20) and the piston rod of the telescopic cylinder (20) is connected with any one of the lower clamping plates (42), and the other one is connected with the base plate (10).

2. The steel mesh feeding mechanism according to claim 1, wherein each clamping assembly (40) further comprises: a flow channel plate (45) and a cover plate (46) disposed above the flow channel plate (45);

a guide cavity (47) for a material belt (50) to pass through is formed between the runner plate (45) and the cover plate (46), a first avoidance hole (451) for avoiding the lower clamping plate (42) is formed in the runner plate (45), and the first avoidance hole (451) is communicated with the guide cavity (47);

the cover plate (46) is provided with a second avoidance hole (461) avoiding the upper clamping plate (41), and the second avoidance hole (461) is communicated with the guide cavity (47).

3. The steel mesh feeding mechanism according to claim 2, further comprising: a hollow guide tube (60) with two open ends;

one end opening of the guide pipe (60) is butted with the guide cavity (47) of any one clamping assembly (40), and the other end extends downwards and then extends to the other clamping assembly (40) along a first horizontal direction.

4. The steel mesh feeding mechanism according to claim 2 or 3, further comprising: a tape (50) positioning assembly; the material belt (50) positioning assembly comprises a connecting block (71), a positioning needle (72) and a first spring (73); the connecting block (71) is connected to the cover plate (46); the positioning needle (72) is vertically connected to the connecting block (71) in a sliding manner; the first spring (73) is arranged between the connecting block (71) and the positioning needle (72), and the first spring (73) is used for driving the positioning needle (72) to move upwards; the cover plate (46) is provided with a third avoidance hole (462) avoiding the positioning needle (72).

5. The steel mesh feeding mechanism according to claim 4, wherein the positioning pin (72) is provided with a boss (721) at the upper part; the first spring (73) is sleeved outside the positioning needle (72), and two ends of the first spring (73) respectively abut against the connecting block (71) and the boss (721).

6. A steel mesh feeding mechanism according to claim 2 or 3, wherein the clamping assembly (40) at the feeding end further comprises: two material pressing components (80) arranged in parallel along a second horizontal direction; the second horizontal direction is perpendicular to the first horizontal direction;

each pressing assembly (80) comprises a pressing block (81), a second spring (82) and a spring mounting block (83);

the spring mounting block (83) is connected to the cover plate (46);

the pressing block (81) is connected to the spring mounting block (83) in a sliding mode along the vertical direction;

the second spring (82) is arranged between the spring mounting block (83) and the pressing block (81), and the second spring (82) is used for driving the pressing block (81) to move downwards;

the cover plate (46) is provided with a fourth avoidance hole (463) for avoiding the pressing block (81).

7. The steel net feeding mechanism according to claim 6, wherein the spring mounting block (83) is extended with an extension part (831) along a horizontal direction; the extension part (831) is provided with a vertically-penetrated matching hole which is matched with the pressing block (81); the lower part of the pressing block (81) is provided with a step (811); two ends of the second spring (82) respectively abut against the step (811) and the extension part (831).

8. The steel mesh feeding mechanism according to claim 7, wherein the pressing block (81) above the extension portion (831) is rotatably connected with a rotating rod (84); when the rotating rod (84) rotates to the first state, the pressing block (81) loosens the material belt (50) in the guide cavity (47); when the rotating rod (84) rotates to the second state, the pressing block (81) presses the material belt (50) in the guide cavity (47).

9. The steel mesh feeding mechanism according to claim 6, wherein a bracket (90) is connected to the discharge end of the base plate (10); the bracket (90) is connected with a sensor (100); the sensing end of the sensor (100) faces upwards.

10. The steel mesh feeding mechanism according to claim 1, wherein a linear rolling guide rail (44) is provided between each lower clamping plate (42) and the base plate (10); the linear rolling guide (44) is disposed in a first horizontal direction.

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