CN218988350U - Multilayer soft medium edge alignment device - Google Patents

Abstract

The utility model relates to the technical field of cloth processing, and provides a multilayer soft medium edge alignment device, wherein a position adjusting structure and a flattening structure are arranged on a workbench, the flattening structure moves back and forth along the workbench under the adjustment of the position adjusting structure, and the flattening structure comprises at least one flattening mechanism and is used for carrying out processing flattening operation on the fabric. The position adjusting structure is arranged, so that the width of the cloth (multi-layer soft medium) can be adjusted according to the requirement, and the edge alignment operation of the cloth (multi-layer soft medium) with various widths can be satisfied; through being equipped with front end pre-clamping mechanism and rear end pre-clamping mechanism, adjust a plurality of positions of cloth (multilayer soft medium), effectively reduce the fold appearance, make the edge of cloth (multilayer soft medium) all align.

Description

Multilayer soft medium edge alignment device

Technical Field

The utility model relates to the technical field of cloth processing, in particular to a multilayer soft medium edge alignment device.

Background

The multi-layer soft medium is generally rolled into a coil stock after production and processing, such as fabric, and is inevitably cut according to a certain size specification in the processing process, or irregular edge positions are cut and trimmed, when the multi-layer soft medium has folds in the processing process, the obtained size has errors, and the later cutting and sewing are uneven or leaks produce defective products; therefore, the multi-layer soft medium needs to be subjected to edge alignment before processing, so that dimensional errors caused by wrinkles are prevented from being generated, and the quality of products is prevented from being influenced.

Disclosure of Invention

In order to solve the problems, the utility model provides the following technical scheme:

the utility model provides a multilayer soft medium edge alignment device which comprises a workbench, wherein a position adjusting structure and a flattening structure are arranged on the workbench, the flattening structure moves back and forth along the workbench under the adjustment of the position adjusting structure, and the flattening structure comprises at least one flattening mechanism and is used for carrying out processing flattening operation on a fabric.

Preferably, the number of the flattening mechanisms is determined according to the required layers of cloth (multi-layer soft medium) of the product.

Further, the flattening mechanism comprises a placing plate, an outer cover, a front-end pre-clamping mechanism and a rear-end pre-clamping mechanism, wherein the front-end pre-clamping mechanism and the rear-end pre-clamping mechanism are placed on the placing plate side by side, the outer cover is connected with the placing plate, and the outer cover covers the front-end pre-clamping mechanism and the rear-end pre-clamping mechanism.

Further, the front end pre-clamping mechanism comprises a first driving piece, a first roller group, a first jacking block and a first upper roller mounting plate, the first roller group comprises a first upper roller and a first lower roller, the first upper roller is fixedly connected with the first upper roller mounting plate, the first upper roller mounting plate is connected with the first driving piece through the first jacking block, and the first upper roller moves up and down under the action of the first driving piece.

Preferably, the first upper roller and the first lower roller are fixedly connected through a bearing seat.

Preferably, a cushion block can be arranged between the first jacking block and the first upper roller mounting plate for connection.

Further, the rear end pre-clamping mechanism comprises a second driving piece, a third driving piece, a second roller group, a second jacking block, a second upper roller mounting plate and a lower roller mounting plate, wherein a first sliding block is arranged on the lower roller mounting plate, a guide rail is arranged on the placing plate, the second driving piece is connected with the lower roller mounting plate through a connecting rod, the second driving piece drives the lower roller mounting plate and the second roller group to move back and forth along the guide rail, the second roller group comprises a second upper roller and a second lower roller, the second upper roller is fixedly connected with the second upper roller mounting plate, the second upper roller mounting plate is connected with the third driving piece through the second jacking block, and the second upper roller moves up and down under the action of the third driving piece.

Preferably, the mounting frame of the third driving member is fixedly connected with the lower roller mounting plate.

Preferably, the second upper roller and the second lower roller may be provided with a baffle, and when the cloth (multi-layer soft medium) is flat and has no wrinkles, the second upper roller and the second lower roller may be provided with a baffle, so that the cloth (multi-layer soft medium) is not adjusted.

Preferably, a cushion block can be arranged between the second jacking block and the second upper roller mounting plate for connection.

Further, the first upper roller mounting plate is connected with a first connecting plate, a first lifting limiting block is arranged on the first connecting plate, and a first induction strip is arranged on the first connecting plate;

the second upper roller mounting plate is connected with a second connecting plate, a second lifting limiting block is arranged on the second connecting plate, and a second induction strip is arranged on the second connecting plate.

Preferably, the first lifting limiting block and the second lifting limiting block are both T-shaped.

Further, a lateral part of front end pre-clamping mechanism and a lateral part of rear end pre-clamping mechanism all are equipped with stop device, stop device includes limiting plate and buffer, the buffer is installed the tip of limiting plate, be equipped with waist type hole on the limiting plate, first lift limit piece with the second plays to rise the stopper and arrange in the waist type hole, the buffer plays the cushioning effect to first lift limit piece with the second plays to rise the stopper, goes up spacing to the lifting of gyro wheel on first and the second, prevents that the lifting from exceeding the limit scope.

Further, an end of the front end pre-clamping mechanism and an end of the rear end pre-clamping mechanism are respectively provided with an induction device, the induction devices comprise mounting seats, two proximity switch sensors are arranged on the mounting seats, the proximity switch sensors are respectively positioned at an upper limit position and a lower limit position of the first roller group or the second roller group, which are moved up and down, and are in induction with the first induction strip or the second induction strip, when the proximity switch sensors sense the first induction strip or the second induction strip, the proximity switch sensors trigger the first driving piece or the third driving piece to stop moving or reversely moving, so that the range of the first roller group or the second roller group, which is moved up and down, is not more than the upper limit and the lower limit, and the lifting distance of the first roller group or the second roller group can be set in a certain range.

Further, a reflecting plate is arranged on the placing plate at one side of the front-end pre-clamping mechanism, three photoelectric switch sensors are arranged on the outer cover of the flattening mechanism arranged on the topmost layer of the workbench, and the photoelectric switch sensors are respectively and correspondingly arranged at the deviation rectifying limit positions of cloth (multi-layer soft medium), the normal position of the cloth (multi-layer soft medium) and the position of the deviation rectifying limit position. When cloth (multi-layer soft medium) is placed on the front-end pre-clamping mechanism, the cloth (multi-layer soft medium) is detected by the photoelectric switch sensor through the reflecting plate, and the cloth (multi-layer soft medium) is judged to be at the polarization correcting limit position according to the detection of the photoelectric switch sensors at different positions, and the normal position of the cloth (multi-layer soft medium) is also at the position where the polarization correcting limit is needed, and the movement of the first driving piece is controlled through the feedback of the photoelectric switch sensor.

Because the distance that the flattening mechanism moves out of the workbench through the position adjusting structure according to the width of the cloth (multi-layer soft medium) is consistent with the width of the cloth (multi-layer soft medium), whether the cloth (multi-layer soft medium) is at the deviation correcting limit position, the normal position of the cloth (multi-layer soft medium) and the position of the limit position to be corrected can be detected through the photoelectric switch sensor.

Further, three groove photoelectric switches are fixedly arranged on one side of the rear end pre-clamping mechanism, and the three groove photoelectric switches are respectively arranged on the upper limit, the in-situ limit and the lower limit of the movement of the rear end pre-clamping mechanism.

Preferably, the rear end pre-clamping mechanism further comprises a lower roller mounting plate, and a groove photoelectric sensing piece is arranged on the lower roller mounting plate; the position of the rear end pre-clamping mechanism can be judged through the induction of the groove photoelectric induction piece and the groove photoelectric switch, and the rear end pre-clamping mechanism is used for controlling the range in which the second driving piece drives the third driving piece to move.

Further, the position adjusting structure comprises a hand wheel, a screw rod support assembly and a second sliding block, wherein the hand wheel is connected with the screw rod support assembly, and the flattening structure moves back and forth along the second sliding block under the action of the hand wheel and the screw rod support assembly.

Preferably, a guide rail is arranged at the bottom of the flattening structure, and the flattening structure moves back and forth along the second sliding block under the action of the hand wheel and the screw rod support assembly.

The distance of the flattening structure moved by the hand wheel can be determined according to the width of the cloth (multi-layer soft medium).

The utility model has the following beneficial effects:

(1) The utility model can adjust the width of cloth (multi-layer soft medium) according to the need by arranging the position adjusting structure, and can meet the requirement of carrying out edge alignment operation on cloth (multi-layer soft medium) with various widths;

(2) The front-end pre-clamping mechanism is arranged to flatten the cloth (multi-layer soft medium), the reflecting plate is arranged at the front-end pre-clamping mechanism, photoelectric switch sensors are respectively arranged at the normal position of the cloth (multi-layer soft medium) and the position needing to be rectified, the cloth (multi-layer soft medium) is detected by the photoelectric switch sensors through the reflecting plate, the cloth (multi-layer soft medium) is judged to be at the polarization rectification limit position according to the detection of the photoelectric switch sensors at different positions, and the movement of the first driving piece is controlled through the feedback of the photoelectric switch sensors at the normal position of the cloth (multi-layer soft medium) or the position needing to be at the polarization rectification limit position, so that the situation of wrinkles is reduced or avoided;

(3) The utility model has the advantages that the rear-end pre-clamping mechanism is arranged, the flattening effect of the cloth (multi-layer soft medium) reaches the optimal state by adjusting the cloth (multi-layer soft medium) in an up-down and left-right omnibearing manner, and meanwhile, the position of the rear-end pre-clamping mechanism is judged by the induction of the groove photoelectric switch and the groove photoelectric induction piece, so that the range of the second driving piece driving the third driving piece to move can be controlled, and the whole operation is more automatic and intelligent;

(4) The utility model adjusts a plurality of orientations of the cloth (multi-layer soft medium) by arranging the front-end pre-clamping mechanism and the rear-end pre-clamping mechanism, thereby effectively reducing the occurrence of wrinkles and enabling the edges of the cloth (multi-layer soft medium) to be aligned.

Drawings

Fig. 1 is a schematic view of the overall mechanism of the present utility model.

Fig. 2 is a schematic view of the internal structure of the present utility model.

Fig. 3 is a schematic view of the flattening structure of the present utility model.

FIG. 4 is a schematic view of the flattening mechanism of the present utility model.

Fig. 5 is a schematic view of the front end pre-clamping mechanism of the present utility model.

Fig. 6 is a schematic side view of the rear end pre-clamping mechanism of the present utility model.

Fig. 7 is another schematic view of the rear end pre-clamping mechanism of the present utility model.

Fig. 8 is a schematic view of a second web placement position of the present utility model.

Fig. 9 is a schematic view of a spacing device of the present utility model.

Fig. 10 is a schematic diagram of an induction device of the present utility model.

Fig. 11 is a schematic view of a position adjustment structure of the present utility model.

Detailed Description

The following detailed description of the embodiments of the utility model, taken in conjunction with the accompanying drawings, should be taken as illustrative of the utility model only and not as limiting, the examples being intended to provide those skilled in the art with a better understanding and reproduction of the technical solutions of the utility model, the scope of the utility model still being defined by the claims.

As shown in fig. 1-2, the utility model provides a multilayer soft medium edge alignment device, which comprises a workbench 1, wherein a position adjusting structure 2 and a flattening structure 3 are arranged on the workbench 1, the flattening structure 3 moves back and forth along the workbench 1 under the adjustment of the position adjusting structure 2, and the flattening structure 3 comprises at least one flattening mechanism 4 for performing processing flattening operation on a fabric.

Preferably, the number of the flattening mechanisms 4 is determined according to the product requirement of several layers of cloth (multi-layer soft medium).

As shown in fig. 3-4, in some preferred embodiments, the flattening mechanism 4 includes a placement plate 41, a cover 42, a front end pre-clamping mechanism 43, and a rear end pre-clamping mechanism 44, where the front end pre-clamping mechanism 43 and the rear end pre-clamping mechanism 44 are placed side by side on the placement plate 41, the cover 42 is connected to the placement plate 41, and the cover 42 covers the front end pre-clamping mechanism 43 and the rear end pre-clamping mechanism 44.

As shown in fig. 5, in some preferred embodiments, the front end pre-clamping mechanism 43 includes a first driving member 431, a first roller group 432, a first lifting block 433, and a first upper roller mounting plate 434, where the first roller group 432 includes the first upper roller 4321 and the first lower roller 4322, the first upper roller 4321 is fixedly connected to the first upper roller mounting plate 434, and the first upper roller mounting plate 434 is connected to the first driving member 431 through the first lifting block 433, and the first upper roller 4321 moves up and down under the action of the first driving member 431.

Preferably, the first upper roller 4321 and the first lower roller 4322 are fixedly connected through a bearing block 430.

Preferably, a cushion block 435 may be provided between the first lifting block 433 and the first upper roller mounting plate 434 for connection.

As shown in fig. 6-7, in some preferred embodiments, the rear end pre-clamping mechanism 44 includes a second driving member 441, a third driving member 442, a second roller group 443, a second jacking block 444, a second upper roller mounting plate 445 and a lower roller mounting plate 446, where the lower roller mounting plate 446 is provided with a first slider 447, the placement plate 41 is provided with a guide rail 410, the second driving member 441 is connected with the lower roller mounting plate 446 through a connecting rod 448, the second driving member 441 drives the lower roller mounting plate 446 and the second roller group 443 to move back and forth along the guide rail 410, the second roller group 443 includes the second upper roller 4431 and a second lower roller 4432, the second upper roller 4431 is fixedly connected with the second upper roller mounting plate 445, the second upper roller mounting plate 445 is connected with the third driving member 441 through the second jacking block 444, and the second upper roller 4431 moves up and down under the action of the third driving member 441.

Preferably, the mounting bracket 4420 of the third driving member 442 is fixedly coupled to the lower roller mounting plate 446.

Preferably, the second driving member 441 may be a three-axis motor.

Preferably, the second upper roller 4431 and the second lower roller 4432 may be provided with a baffle 4433, and when the cloth (multi-layer soft medium) is flat and has no wrinkles, the second upper roller 4431 and the second lower roller 4432 may be provided with the baffle 4433, so that the cloth (multi-layer soft medium) is not adjusted.

Preferably, a cushion block 435 may be provided between the second lifting block 444 and the second upper roller mounting plate 445 for connection.

As shown in fig. 8, in some preferred embodiments, the first upper roller mounting plate 434 is connected to the first connecting plate 5, the first connecting plate 5 is provided with a first lifting limiting block 51, and the first connecting plate 5 is provided with a first sensing strip 52;

the second upper roller mounting plate 445 is connected with the second connecting plate 6, a second lifting limiting block 61 is arranged on the second connecting plate 6, and a second sensing strip 62 is arranged on the second connecting plate 6.

Preferably, the first lifting limiting block 51 and the second lifting limiting block 61 are both T-shaped.

As shown in fig. 9, in some preferred embodiments, a side portion of the front end pre-clamping mechanism 43 and a side portion of the rear end pre-clamping mechanism 44 are provided with a limiting device 7, the limiting device 7 includes a limiting plate 71 and a buffer 72, the buffer 72 is mounted at an end portion of the limiting plate 71, a waist-shaped hole 711 is formed in the limiting plate 71, the first lifting limiting block 51 and the second lifting limiting block 61 are disposed in the waist-shaped hole 711, and the buffer 72 plays a role in buffering the first lifting limiting block 51 and the second lifting limiting block 61, and limits lifting of the first upper roller 4321 and the second upper roller 4431, so that lifting is prevented from exceeding a limited range.

Preferably, a limiting device 7 disposed at a side portion of the rear end pre-clamping mechanism 44 is placed on the lower roller mounting plate 446, and the specific limiting device 7 is connected with the connecting rod 448, and meanwhile, the connecting rod 448 can be connected with the lower roller mounting plate 446, so as to drive the lower roller mounting plate 446 to move.

As shown in fig. 10, in some preferred embodiments, an end portion of the front end pre-clamping mechanism 43 and an end portion of the rear end pre-clamping mechanism 44 are both provided with a sensing device 8, the sensing device 8 includes a mounting seat 81, two proximity switch sensors 82 are provided on the mounting seat 81, the proximity switch sensors 82 are respectively located at an upper limit position and a lower limit position of the first roller set 432 or the second roller set 443, which are moved up and down, and are sensed by the first sensing strip or the second sensing strip, the proximity switch sensors 82 are sensed by the first sensing strip or the second sensing strip, and when the proximity switch sensors 82 sense the first sensing strip or the second sensing strip, the proximity switch sensors 82 trigger the first driving member 431 or the third driving member 442 to stop moving or reverse moving, so as to ensure that the first roller set 432 or the second roller set 443 is moved up and down within a range not exceeding the upper limit and the lower limit, and the lifting distance of the first roller set 432 or the second roller set 443 can be set within a certain range.

In some preferred embodiments, the placing plate 41 located at one side of the front end pre-clamping mechanism 43 is provided with a reflecting plate 411, and the outer cover of the flattening mechanism 3 disposed at the topmost layer of the workbench 1 is provided with three photoelectric switch sensors (shielding not shown), where the photoelectric switch sensors (shielding not shown) are respectively and correspondingly disposed at the deviation rectifying limit positions of the cloth (multi-layer soft medium), the normal position of the cloth (multi-layer soft medium) and the deviation rectifying limit position to be rectified. When the cloth (multi-layer soft medium) is placed on the front end pre-clamping mechanism 43, the cloth (multi-layer soft medium) is detected by the photoelectric switch sensor through the reflecting plate 411, and the cloth (multi-layer soft medium) is judged to be at the polarization correcting limit position according to the detection of the photoelectric switch sensors at different positions, and the movement of the first driving part 431 is controlled through the feedback of the photoelectric switch sensor at the normal position of the cloth (multi-layer soft medium) or at the position where the polarization correcting limit is required.

Because the distance that the flattening mechanism 4 moves out of the workbench 1 through the position adjusting structure 2 according to the width of the cloth (multi-layer soft medium) is consistent with the width of the cloth (multi-layer soft medium), whether the cloth (multi-layer soft medium) is at the limit position of deviation correction or not can be detected through the photoelectric switch sensor, and the normal position of the cloth (multi-layer soft medium) and the limit position of deviation correction are needed.

In some preferred embodiments, as shown in fig. 7, three slot photoelectric switches 10 are fixedly arranged on one side of the rear end pre-clamping mechanism 44, and are respectively arranged on the upper limit, the home position and the lower limit of the movement of the rear end pre-clamping mechanism 44.

Preferably, the lower roller mounting plate 446 is provided with a groove photoelectric sensing piece 4461; the position of the rear end pre-clamping mechanism 44 can be determined by sensing the slot photoelectric sensing piece 4461 and the slot photoelectric switch 10, so as to control the moving range of the roller mounting plate 446 under the driving of the second driving piece 441.

As shown in fig. 11, in some preferred embodiments, the position adjustment structure 2 includes a hand wheel 21, a screw support assembly 22, and a second slider 23, where the hand wheel 21 is connected to the screw support assembly 22, and the flattening structure 3 moves back and forth along the second slider 23 under the action of the hand wheel 21 and the screw support assembly 22.

Preferably, a guide rail 31 is arranged at the bottom of the flattening structure 3, and the flattening structure 3 moves back and forth along the second sliding block 23 under the action of the hand wheel 21 and the screw support assembly 22; the distance of the flattening structure moved by the hand wheel can be determined according to the width of the cloth (multi-layer soft medium).

Preferably, the screw support assembly 22 is an important component of the connection between the screw and the motor, which allows the bearing to perform the best bearing performance, and helps the user to better adjust the contact ball bearing while realizing the supporting function; the functional advantages of the ultra-small supporting unit are fully exerted, so that the mechanical equipment and the bearing have the use effect of high precision in the running process, and very stable rotation performance can be obtained; in the practical application process, precision errors rarely occur, and the lead screw supporting seat is guaranteed to fully exert better effects and functions.

While preferred embodiments of the present application have been described, additional variations and modifications in those embodiments may occur to those skilled in the art once they learn of the basic inventive concepts. It is therefore intended that the following claims be interpreted as including the preferred embodiments and all such alterations and modifications as fall within the scope of the application.

Claims (10)

1. The utility model provides a multilayer soft medium edge alignment device, includes the workstation, its characterized in that, be equipped with position adjustment structure and flattening structure on the workstation, flattening structure is in the regulation of position adjustment structure is followed the workstation back-and-forth movement, flattening structure includes at least one flattening mechanism, carries out processing flattening operation to the surface fabric.

2. The multi-layer soft media edge alignment device of claim 1, wherein the flattening mechanism comprises a placement plate, a housing, a front end pre-clamping mechanism, and a rear end pre-clamping mechanism, the front end pre-clamping mechanism and the rear end pre-clamping mechanism being placed side-by-side on the placement plate, the housing being coupled to the placement plate, the housing the front end pre-clamping mechanism and the rear end pre-clamping mechanism.

3. The multilayer soft medium edge alignment device according to claim 2, wherein the front end pre-clamping mechanism comprises a first driving member, a first roller group, a first jacking block and a first upper roller mounting plate, the first roller group comprises a first upper roller and a first lower roller, the first upper roller is fixedly connected with the first upper roller mounting plate, the first upper roller mounting plate is connected with the first driving member through the first jacking block, and the first upper roller moves up and down under the action of the first driving member.

4. The multilayer soft medium edge alignment device according to claim 3, wherein the rear end pre-clamping mechanism comprises a second driving piece, a third driving piece, a second roller group, a second jacking block, a second upper roller mounting plate and a lower roller mounting plate, a first sliding block is arranged on the lower roller mounting plate, a guide rail is arranged on the placement plate, the second driving piece is connected with the lower roller mounting plate through a connecting rod, the second driving piece drives the lower roller mounting plate and the second roller group to move back and forth along the guide rail, the second roller group comprises a second upper roller and a second lower roller, the second upper roller is fixedly connected with the second upper roller mounting plate, the second upper roller mounting plate is connected with the third driving piece through the second jacking block, and the second upper roller moves up and down under the action of the third driving piece.

5. The multi-layer soft media edge alignment device of claim 4, wherein the first upper roller mounting plate is connected to a first connecting plate, a first lifting limiting block is arranged on the first connecting plate, and a first sensing strip is arranged on the first connecting plate;

the second upper roller mounting plate is connected with a second connecting plate, a second lifting limiting block is arranged on the second connecting plate, and a second induction strip is arranged on the second connecting plate.

6. The multi-layer soft medium edge alignment device according to claim 5, wherein a side portion of the front end pre-clamping mechanism and a side portion of the rear end pre-clamping mechanism are provided with limiting devices, the limiting devices comprise limiting plates and buffering devices, the buffering devices are mounted at the end portions of the limiting plates, and waist-shaped holes are formed in the limiting plates.

7. The multi-layer soft medium edge alignment device according to claim 6, wherein an end of the front end pre-clamping mechanism and an end of the rear end pre-clamping mechanism are respectively provided with a sensing device, the sensing device comprises a mounting seat, two proximity switch sensors are arranged on the mounting seat, and the proximity switch sensors are respectively positioned at an upper limit position and a lower limit position of the first roller group or the second roller group which move up and down and are sensed by a first sensing strip or a second sensing strip.

8. The multilayer soft medium edge alignment device according to claim 6, wherein a reflecting plate is arranged on the placing plate at one side of the front end pre-clamping mechanism, three photoelectric switch sensors are arranged on the outer cover of the flattening mechanism arranged on the topmost layer of the workbench, and the photoelectric switch sensors are respectively and correspondingly arranged at the deviation rectifying limit positions of the multilayer soft medium, the normal position of the multilayer soft medium and the position needing to rectify the deviation.

9. The multi-layer soft medium edge alignment device according to claim 6, wherein three groove photoelectric switches are fixedly arranged on one side of the rear end pre-clamping mechanism, and the groove photoelectric switches are respectively arranged at an upper limit position, a home position and a lower limit position of the rear end pre-clamping mechanism.

10. The multi-layer soft media edge alignment device of claim 1, wherein the position adjustment structure comprises a hand wheel, a screw support assembly, and a second slider, the hand wheel is connected to the screw support assembly, and the flattening structure moves back and forth along the second slider under the action of the hand wheel and the screw support assembly.

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