CN211761949U - Feeding system for cutting wool board - Google Patents

Abstract

The utility model belongs to the technical field of the fine hair board cuts, concretely relates to a feeding system for fine hair board cuts. The utility model comprises a feeding component arranged at the feeding end of a blanking machine and a receiving component arranged at the discharging end of the blanking machine, wherein the feeding component comprises a feeding frame, a feeding plate in the shape of a horizontal plate is arranged at the working table top of the feeding frame, and the upper plate surface of the feeding plate forms a placing surface for placing a wool board; the feeding assembly also comprises a pushing mechanism used for pushing the feeding plate to generate feeding action along the working table surface, and the pushing mechanism is driven by a driving source and performs directional guiding action through a guiding mechanism; connect the material subassembly: the material receiving machine comprises a material receiving machine frame, wherein the height of a material receiving surface of the material receiving machine frame is consistent with that of a placing surface. The utility model discloses can the efficient realization to the fast punching flow of production board to when guaranteeing die-cut efficiency, also can effectively reduce operating personnel's work burden, work is very reliable stable.

Description

Feeding system for cutting wool board

Technical Field

The utility model belongs to the technical field of the fine hair board cuts, concretely relates to a feeding system for fine hair board cuts.

Background

The pile board usually uses a base material as a bottom, and an adhesive layer is uniformly coated on the surface of the base material, and then an upright, uniform and compact pile layer is planted on the adhesive layer, and is often used for manufacturing cushion body structures such as foot pads, covering pads and the like. In actual production, the flocked plate needs to be punched into various special-shaped structures according to different application objects. The existing traditional punching mode is as follows: the artificial supporting of the flocked plate is intermittently fed from the feeding end of the die cutting machine with rhythm, and discharged from the discharging end; in the overshoot, along with the downward pressing and punching action of the die head of the punching machine, the indentation meeting the requirement of the specific shape can be punched on the whole flannelette plate, and then the finished plates are sequentially pulled out along the indentation one by one. Obviously, the manual feeding mode has the common defects of high labor intensity of operators and low working efficiency. Meanwhile, due to the fact that manual feeding is adopted, due to the fact that the feeding angle of the wool board is inclined, even feeding is not stable enough and other factors, a series of production defects that punching leftover materials are too much, punching rejection rate is improved and the like can occur, and therefore the actual operation benefit of a manufacturer is adversely affected.

Disclosure of Invention

The utility model aims at overcoming the not enough of above-mentioned prior art, provide a feeding system that is used for the fine hair board that rational in infrastructure and degree of automation is high and cut, can the efficient realization to the quick die-cut flow of production board to when guaranteeing die-cut efficiency, also can effectively reduce operating personnel's work burden, work is very reliable stable.

In order to achieve the above purpose, the utility model adopts the following technical scheme:

the utility model provides a feeding system for fine hair board cuts which characterized in that: including arranging in the feeding subassembly of die cutter feed end and arranging in the subassembly that connects material of die cutter discharge end, wherein:

a feeding assembly: the feeding machine comprises a feeding rack, wherein a horizontal flat-plate-shaped feeding plate is arranged on the working table top of the feeding rack, the upper plate surface of the feeding plate forms a placing surface for placing a wool board, and the height of the placing surface is consistent with that of the working surface of a die cutting machine; the feeding assembly also comprises a pushing mechanism used for pushing the feeding plate to generate feeding action along the working table surface, and the pushing mechanism is driven by a driving source and performs directional guiding action through a guiding mechanism;

connect the material subassembly: the material receiving machine comprises a material receiving machine frame, wherein the height of a material receiving surface of the material receiving machine frame is consistent with that of a placing surface.

Preferably, the driving source is a servo motor, the pushing mechanism further comprises a synchronous conveying belt, the conveying direction of the synchronous conveying belt is the same as the advancing direction of the feeding plate, a positioning block is embedded on the synchronous conveying belt, the top end face of the positioning block fixes the bottom end face of the pushing block, and a face abutting fit relationship is formed between the top end face of the pushing block and the tail end face of the feeding plate; the guide mechanism comprises a linear guide rail and a linear guide block which is matched with the linear guide rail in a sliding and guiding manner, the action direction of the linear guide block is the same as the conveying direction of the synchronous conveying belt, and the top end face of the linear guide block is also fixedly connected to the bottom end face of the push block.

Preferably, the driving source, the synchronous conveying belt, the positioning block and the guide mechanism are a group of pushing units, and the two groups of pushing units are symmetrically arranged on two sides below the feeding plate.

Preferably, the top end surface of the feeding machine frame is provided with four groups of bearing plates which are respectively arranged between the synchronous conveying belt and the guide mechanism and between the guide mechanism and the guide mechanism; the upper plate surface of the bearing plate forms the working table surface, and the length direction of the bearing plate is parallel to the guide direction of the guide mechanism.

Preferably, the bearing plate is detachably fixed on the feeding rack through a countersunk screw.

Preferably, the ejector pad appearance is "L" word block form, and the ejector pad back-off formula is fixed in sharp guide block and locating piece top face department to it forms the constant head tank that can supply the flitch tail to block in to enclose jointly between "L" type breach and the loading board upper plate face of ejector pad to make the ejector pad.

Preferably, the lead on the pushing block vertically penetrates through the mounting hole, and the mounting screw lead vertically penetrates through the mounting hole and then is fastened at the tail end of the feeding plate.

Preferably, the material receiving surface of the material receiving rack is provided with rollers in an array shape in a rotating manner, and the wheel shafts of the rollers are vertical to the advancing direction of the feeding plate.

Preferably, the upper plate surface of the feeding plate is fixedly adhered or fixed with positioning strips through threads, and the outline of an area formed by enclosing the fixed positioning strips is matched with the outline of the wool plate to be punched.

The beneficial effects of the utility model reside in that:

1) the traditional manual feeding and punching mode is abandoned, the feeding assembly and the receiving assembly are added, the feeding assembly serves as a mounting platform of a feeding bearing platform and a pushing mechanism, the receiving assembly serves as a receiving bearing platform, and finally the process operation purpose that the wool board is placed on a feeding plate, the wool board is pushed forward by the pushing mechanism and enters a punching area of a punching machine, the wool board is punched to form an indentation, and the wool board is continuously pushed into a receiving rack by the pushing mechanism is achieved. The operator only needs to complete the placement of the wool board and the subsequent pulling-out operation of the finished board. Even if necessary, directly purchase the punching press lathe that can independently accomplish the operation of punching out of finished product board, the purpose of the arrangement of material receiving frame is only for taking off the leftover bits on the delivery sheet this moment, and work efficiency can obtain further improvement.

To sum up, the utility model discloses can the efficient realization to the fast punching flow of production board to when guaranteeing die-cut efficiency, also can effectively reduce operating personnel's work burden, work is very reliable stable.

2) The pushing mechanism can be realized by various structures, such as a crank-slider mechanism and a motor for driving to realize front and back movement, or a cylinder or a hydraulic cylinder for finishing a directional movement process. The utility model discloses preferred servo motor that adopts is as the driving source to realize the directional accurate action of delivery sheet with synchronous conveyer belt collocation guiding mechanism's mode. The synchronous conveyer belt is matched with a servo motor, so that accurate control action of a specified position at specified time can be realized; once the synchronous conveying belt starts to act, the pushing block can be driven by the positioning block, so that the pushing block pushes the feeding plate to move forwards along the working table under the guiding action of the guiding mechanism, and finally, the precise feeding action is finished.

3) The arrangement of the bearing plate has the bearing function of the worktable surface, so that the feeding plate is used for bearing a heavier feeding plate; on the other hand, the feeding plate has the function of a guide plate, so that the feeding plate can slide along the length direction of the bearing plate. After actual assembly, the positioning blocks and the linear guide blocks are not loaded or only bear slight weight, and most of the weight is loaded on the plurality of bearing plates, so that the actual service lives of the guide mechanism, the synchronous conveying belt and the driving source are ensured. On this basis, if the loading board produces the frictional wear situation, and when wearing and tearing were too much, detachable cooperation between accessible loading board and the feeder frame was changed in good time to further promote whole high life who constructs.

4) The push block is in an L-shaped block shape so as to be matched with the bearing plate to form a positioning groove, and the tail end of the feeding plate is clamped in. When necessary, go into the constant head tank at loading board tail end card even after, the rethread mounting screw runs through the trough rim of constant head tank and fixes on the delivery sheet to realize advancing with going into of ejector pad and delivery sheet and go out the function, thereby can further promotion the utility model discloses an actual work efficiency.

5) The material receiving assembly only has the material receiving function, so that the roller can reduce the forward resistance of the feeding plate as much as possible. A plurality of location strips are preferably arranged to face department on the delivery sheet to the model size according to current fine hair board divides places the region, thereby does benefit to the actual fixed of fine hair board, and ensures that the fixed area of fine hair board just is in the working area of die-cutting machine in, in order to promote the utility model discloses operational reliability.

Drawings

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

FIG. 2 is a partial enlarged view of part I of the present invention;

FIG. 3 is a top view of FIG. 1;

FIG. 4 is a top view of the pushing mechanism during feeding;

fig. 5 is a schematic perspective view of the pushing mechanism.

The utility model discloses each reference numeral is as follows with the actual corresponding relation of part name:

a-die cutter b-positioning groove

10-feeding assembly 11-feeding frame

12 a-drive source 12 b-synchronous conveyor belt 12 c-positioning block

12 d-push block 12 e-linear guide rail 12 f-linear guide block

13-bearing plate 13 a-countersunk head screw

20-material receiving component 21-material receiving rack 22-roller

30-feeding plate 31-positioning strip

Detailed Description

For ease of understanding, the specific structure and operation of the present invention will be further described herein with reference to fig. 1-5:

the utility model discloses a concrete structure is shown in fig. 1-5, and its major structure includes feeding component 10 and connects material subassembly 20 two parts, wherein:

taking the embodiment shown in fig. 1-5 as an example, it can be seen that the feeding assembly 10 comprises a feeding frame 11, on which feeding frame 11 four carrier plates 13 are arranged in the feeding direction of the pile boards. The upper plate surfaces of the bearing plates 13 are on the same horizontal plane to form a working plane, and the height of the working plane is matched with the height of the material receiving surface at the material receiving assembly 20 and the height of the working surface of the die cutting machine a.

In fig. 5 it can be seen that the parts are arranged in sequence, from the outside to the inside in the direction of arrangement of the carrying floors 13, in the manner of an arrangement of a set of guide means, a set of synchronous conveyor belts 12b with positioning blocks 12c, a further set of synchronous conveyor belts 12b with positioning blocks 12c, and a further set of guide means. The guide mechanism includes a linear guide rail 12e and a linear guide block 12f that reciprocates linearly in the guide direction of the linear guide rail 12 e. In actual operation, the pushing block 12d shown in fig. 2 and 5 is fixed to the top end surfaces of the positioning block 12c and the linear guide block 12f, and at the same time, a positioning groove b shown in fig. 2 is formed between the pushing block and the upper plate surface of the supporting plate 13. When the feeding plate 30 is placed, the main weight is borne by the four carrying plates 13, and the feeding plate is pushed by the pushing block 12d to move linearly along the guiding direction of the linear guide rail 12 e. If necessary, the feeding plate 30 and the pushing block 12d can be directly fixed even by mounting screws, so that the pushing mechanism has the functions of feeding and returning plates. Servo motor drives synchronous conveyer belt 12b as driving source 12a, then the pay-off rhythm of control pay-off board 30 that can be accurate, in order to promote the utility model discloses a operational reliability and accuracy.

Considering the size change of the flocked plate, or considering the passing of the positioning groove b, the feeding plate 30 with different sizes can be replaced at any time. As shown in fig. 5, several positioning bars 31 can be fixed directly on the feeding plate 30 with the largest size by means of screw fixation or even velcro fixation, etc. to divide the placement area according to the size of the current slate. The above-mentioned arrangement of the positioning strips 31 is advantageous for the actual fixation of the pile boards and ensures that the fixation area of the pile boards is just in the working area of the blanking machine a. The material receiving assembly 20 only has the material receiving function, so that the roller 22 is arranged to reduce the forward resistance of the feeding plate 30 as much as possible; it is evident that the bearing surface formed by the rollers 22 now constitutes the receiving surface as shown in fig. 1 and 3-4.

In order to further understand the present invention, the structure shown in fig. 1-5 is taken as an example, and the specific working procedures of the present invention are as follows:

1) preparation phase

Firstly, a feeding plate 30 with a proper size is selected according to the size of the current velvet plate. The feeding plate 30 is snapped into the positioning slot b as shown in fig. 2 and 5 and properly adjusted to center the working area of the die cutter a. If necessary, the pushing block 12d and the feeding plate 30 are fastened together by mounting screws. At this moment, the working state of the utility model is shown in figures 1-3.

2) Working phase

Die cutter a is turned on and drive source 12a is turned on in synchronization. Under the action of the servo motor as the driving source 12a, as shown in fig. 5, the synchronous conveyor belt 12b starts to move and drives the positioning block 12c to move forward; the positioning block 12c moves forward, and the pushing block 12d is pulled to generate follow-up action. The pushing block 12d starts to generate pushing action under the sliding guiding action of the bearing and guiding mechanism of the bearing plate 13, so that the feeding plate 30 is pushed to generate feeding action. The feeding plate 30 enters the working area of the die cutting machine a section by section with rhythm under the driving of the servo motor and is die-cut section by section; the head end of the feeding plate 30 starts to gradually enter the material receiving surface of the material receiving rack 21. At this moment, the working state of the utility model is as shown in fig. 4.

After the pile boards on the feeding board 30 are all punched, an operator pulls out the finished board along the punching mark at the material receiving assembly 20 and removes the leftover materials of the pile boards. At this point, the feed plate 30 is pushed back manually; or after the screw is fixedly installed, the feeding plate 30 is pulled back by means of the reverse rotation action of the servo motor so as to replace a new flocked plate, thereby reciprocating.

Of course, the above-described arrangements are merely illustrative of the structures in the specific embodiments shown in FIGS. 1-5; in actual operation, if other driving sources 12a are adopted instead of only adopting the servo motor, the linear guide 12e can be completely realized by other ways such as grooved rail, and even the roller is arranged at the material receiving surface to receive the material instead of the roller 22, and these conventional changes in the original structure and function of the present invention should be regarded as equivalent or similar designs and fall within the protection scope of the present invention.

Claims (9)

1. The utility model provides a feeding system for fine hair board cuts which characterized in that: including arranging in feeding subassembly (10) of die cutting machine (a) feed end and arranging in receiving subassembly (20) of die cutting machine (a) discharge end, wherein:

feed assembly (10): the velvet board cutting machine comprises a feeding rack (11), wherein a horizontal flat-plate-shaped feeding plate (30) is arranged on the working table top of the feeding rack (11), the upper plate surface of the feeding plate (30) forms a placing surface for placing a velvet board, and the height of the placing surface is consistent with that of the working surface of a punching machine (a); the feeding assembly (10) further comprises a pushing mechanism for pushing the feeding plate (30) to generate feeding action along the working table surface, and the pushing mechanism is driven by a driving source (12a) and performs directional guiding action through a guiding mechanism;

connect material subassembly (20): the material receiving machine comprises a material receiving machine frame (21), wherein the height of a material receiving surface of the material receiving machine frame (21) is consistent with that of a placing surface.

2. A feed system for cutting of a pile board according to claim 1, characterised in that: the driving source (12a) is a servo motor, the pushing mechanism further comprises a synchronous conveying belt (12b), the conveying direction of the synchronous conveying belt (12b) is the same as the advancing direction of the feeding plate (30), a positioning block (12c) is embedded on the synchronous conveying belt (12b), the bottom end face of a pushing block (12d) is fixed on the top end face of the positioning block (12c), and a face abutting fit relation is formed between the head end face of the pushing block (12d) and the tail end face of the feeding plate (30); the guide mechanism comprises a linear guide rail (12e) and a linear guide block (12f) which is matched with the linear guide rail (12e) in a sliding guide mode, the action direction of the linear guide block (12f) is the same as the conveying direction of the synchronous conveying belt (12b), and the top end face of the linear guide block (12f) is also fixedly connected to the bottom end face of the push block (12 d).

3. A feed system for cutting of a pile board according to claim 2, characterised in that: the conveying device is characterized in that a driving source (12a), a synchronous conveying belt (12b), a positioning block (12c) and a guide mechanism are used as a group of pushing units, and the two groups of pushing units are symmetrically arranged on two sides below a feeding plate (30).

4. A feed system for cutting of a pile board according to claim 3, characterised in that: the top end face of the feeding rack (11) is provided with four groups of bearing plates (13), and the four groups of bearing plates (13) are respectively arranged between the synchronous conveying belt (12b) and the guide mechanism and between the guide mechanism and the guide mechanism; the upper plate surface of the bearing plate (13) forms the working table surface, and the length direction of the bearing plate (13) is parallel to the guide direction of the guide mechanism.

5. A feed system for cutting of a pile board according to claim 4, characterised in that: the bearing plate (13) is detachably fixed on the feeding rack (11) through a countersunk head screw (13 a).

6. A feed system for cutting of a pile board according to claim 4, characterised in that: the pushing block (12d) is in an L-shaped block shape, and the pushing block (12d) is fixed at the top end faces of the linear guide block (12f) and the positioning block (12c) in a reverse buckling mode, so that an L-shaped notch of the pushing block (12d) and the upper plate face of the bearing plate (13) are jointly enclosed to form a positioning groove (b) for clamping the tail end of the feeding plate (30).

7. A feed system for cutting of a pile board according to claim 6, characterised in that: the lead on the push block (12d) vertically penetrates through the mounting hole, and the mounting screw lead vertically penetrates through the mounting hole and then is fastened at the tail end of the feeding plate (30).

8. A feed system for cutting of pile boards according to claim 1 or 2 or 3 or 4 or 5 or 6, characterised in that: the material receiving surface of the material receiving rack (21) is provided with rollers (22) in an array shape in a rotating mode, and the wheel shafts of the rollers (22) are perpendicular to the advancing direction of the feeding plate (30).

9. A feed system for cutting of pile boards according to claim 1 or 2 or 3 or 4 or 5 or 6, characterised in that: and positioning strips (31) are fixedly adhered or screwed on the upper plate surface of the feeding plate (30), and the outline of an area formed by enclosing after the positioning strips (31) are fixed is matched with the outline of the wool plate to be punched.

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