CN211112568U - Cut-parts piece device - Google Patents

Abstract

The utility model relates to a cut-parts piece device. This cut-parts piece device includes cut-parts plummer, sewing mechanism, mechanism and the workstation of rectifying. This cut-parts piece device can carry out the piece to a plurality of length differences treating the processing cut-parts. In the process of splicing, the deviation correcting mechanism acts to align the sewing ends of the longer cut pieces and the shorter cut pieces. In the process of splicing, the cutting pieces do not need to be manually adjusted by an operator, and the sewing ends of the cutting pieces can be aligned under the action of the deviation correcting wheel and the deviation correcting supporting plate, so that the workload of the operator can be effectively reduced, and the production efficiency is improved. The method for splicing the cut pieces by using the cut piece splicing device is simple to operate, and only the cut pieces are manually sleeved on the cut piece bearing table to be ready for sewing. In the process of splicing, the cutting pieces do not need to be manually adjusted, the workload of operators can be effectively reduced, and the production efficiency is improved.

Description

Cut-parts piece device

Technical Field

The utility model belongs to the technical field of the textile technology and specifically relates to a cut-parts piece device is related to.

Background

In the field of textile technology, it is often necessary to splice cut pieces of different lengths, such as rib cut pieces with other cut pieces. Because rib cut pieces have greater elasticity and extensibility when stretched in the transverse direction, they are often used in articles of clothing that require some elasticity, such as jerseys, cuffs, collars, and pants cuffs, to name a few. In the production process, the rib cut pieces and other cut pieces are sewn to obtain corresponding rib fabrics so as to meet the design and use requirements of clothing products. Generally, the length of the rib cut piece is smaller than that of other cut pieces spliced with the rib cut piece, so that uniform sewing is difficult to achieve in the splicing and sewing process. The traditional sewing method is to make the rib cut pieces into a cylinder shape, then to be sleeved into the cut pieces spliced with the rib cut pieces, then to press the rib cut pieces and the cut pieces in a sewing mechanism, and then to sew the rib cut pieces and the cut pieces. During the sewing process, the cut pieces need to be manually rotated, and the sewing ends of the cut pieces need to be aligned; at the same time, manual adjustment of the cut pieces is required to make the stitching uniform. Such a sewing process requires a large amount of manual operations, and is cumbersome in operation and inefficient in production.

SUMMERY OF THE UTILITY MODEL

Based on this, it is necessary to provide a cut-parts jointing device which is simple in operation, high in efficiency and suitable for jointing cut-parts with different lengths.

A cut-part splicing and sewing device comprises a cut-part bearing platform, a sewing mechanism, a deviation correcting mechanism and a workbench;

the cutting piece bearing table can rotate to drive the inner cutting piece and the outer cutting piece which are sleeved on the cutting piece bearing table and are arranged in an overlapped mode to rotate;

the sewing mechanism is used for splicing the inner cut piece and the outer cut piece;

the deviation rectifying mechanism comprises a deviation rectifying wheel and a deviation rectifying supporting plate which are respectively and movably arranged on the workbench; the relative positions of the deviation rectifying wheel, the deviation rectifying supporting plate and the cut piece bearing table are adjustable; the deviation rectifying wheel can move to be abutted to the deviation rectifying supporting plate.

In one embodiment, the outer periphery of the rectification wheel is recessed to form a plurality of wheel grooves.

In one embodiment, each wheel groove is provided with a rotatable deviation rectifying sub wheel; the deviation rectifying sub-wheel protrudes out of the outer periphery of the deviation rectifying wheel.

In one embodiment, the deviation correcting mechanism further comprises a connecting rod and a first driving mechanism;

the connecting rod is rotatably arranged on the workbench, one end of the connecting rod is connected with the deviation rectifying wheel, and the other end of the connecting rod is connected with the first driving mechanism; the first driving mechanism adjusts the relative position of the deviation rectifying wheel and the cut piece bearing table through the connecting rod.

In one embodiment, the deviation correcting mechanism further comprises a second driving mechanism; the second driving mechanism is connected with the deviation rectifying supporting plate to adjust the relative position of the deviation rectifying supporting plate and the cut piece bearing table.

In one embodiment, the cut piece splicing and sewing device further comprises a material pushing plate; the scraping wings are movably arranged on the cut piece bearing table to complete the splicing of the inner cut piece and the outer cut piece.

In one embodiment, the material pushing plate is bent to form a first material pushing arm and a second material pushing arm; when the cut-parts are sleeved on the cut-parts bearing table, the first pushing arm or the second pushing arm can stretch into the inner cut-parts and between the cut-parts bearing table.

In one embodiment, the included angle between the first pushing arm and the second pushing arm is 90 °.

In one embodiment, the cut-part splicing and sewing device further comprises a bearing auxiliary mechanism, wherein the bearing auxiliary mechanism comprises a stretching component movably arranged on the workbench and a third driving mechanism connected with the stretching component; the third driving mechanism is used for adjusting the relative position of the spreading assembly and the cut piece bearing table;

when the cut-parts are sleeved on the cut-parts bearing table, the opening component can stretch into the inner cut-parts and between the cut-parts bearing table.

In one of them embodiment, cut-parts piece device still includes position detection device, position detection device locates in order to be used for detecting on the cut-parts plummer interior cut-parts, the sewing end of outer cut-parts is whether to align.

The cutting piece splicing and sewing device comprises a cutting piece bearing platform, a sewing mechanism, a deviation rectifying mechanism and a workbench. The cut-parts plummer can rotate in order to drive the cover locate cut-parts plummer on overlap interior cut-parts, the rotation of outer cut-parts that set up. The sewing mechanism is used for splicing the inner cut piece and the outer cut piece. The deviation correcting mechanism comprises a deviation correcting wheel and a deviation correcting supporting plate which are respectively and movably arranged on the workbench; the relative positions of the deviation rectifying wheel, the deviation rectifying supporting plate and the cut piece bearing table are adjustable; the deviation rectifying wheel can move to be abutted to the deviation rectifying supporting plate. This cut-parts piece device can carry out the piece to a plurality of length differences treating the processing cut-parts. In the splicing process, the shorter cut pieces (inner cut pieces) are sleeved on the cut piece bearing table, then the relative positions of the deviation rectifying supporting plates and the cut piece bearing table are adjusted, the longer cut pieces (outer cut pieces) are sleeved on the cut piece bearing table, and the deviation rectifying supporting plates are located between the inner cut pieces and the outer cut pieces. The inner cut piece and the outer cut piece are spliced through a sewing mechanism. In the process of splicing, the deviation rectifying wheel presses the outer cut piece on the deviation rectifying supporting plate, and the outer cut piece is aligned with the sewing end of the inner cut piece under the matching action of the deviation rectifying wheel and the deviation rectifying supporting plate. When sewing up to the preset position of the overlapped cut pieces formed by the inner cut piece and the outer cut piece, the deviation rectifying supporting plate resets, and the sewing mechanism continues to move again to finish the seam splicing. In the process of splicing, the cutting pieces do not need to be manually adjusted by an operator, and the sewing ends of the cutting pieces can be aligned under the action of the deviation correcting wheel and the deviation correcting supporting plate, so that the workload of the operator can be effectively reduced, and the production efficiency is improved.

Drawings

Fig. 1 is a schematic view of relative positions of an inner panel and an outer panel in an embodiment of the present invention;

fig. 2 is a schematic structural view of a cut-part seaming device in an embodiment of the present invention;

fig. 3 is a schematic mechanism diagram of an embodiment of the present invention;

FIG. 4 is a schematic view of an embodiment of the present invention in which the cut-parts carrier is covered with the inner cut-parts;

fig. 5 is a schematic view of the outer cut-parts covering on the cut-parts carrier in an embodiment of the present invention.

The notation in the figure is:

10. a cutting piece splicing device; 11. a cut piece bearing table; 12. a sewing mechanism; 13. a deviation rectifying mechanism; 14. a work table; 15. a load-bearing auxiliary mechanism; 16. a position detection device; 17. inner cutting pieces; 18. outer cutting pieces; 121. a material pushing plate; 122. a presser foot; 123. a wire breaking device; 131. a deviation rectifying wheel; 132. correcting a deviation supporting plate; 133. a connecting rod; 134. a first drive mechanism; 135. a second drive mechanism; 136. a fourth drive mechanism; 151. a distraction assembly; 152. a third drive mechanism; 171. the bone position of the inner cut piece; 181. the outer cut-parts bone position; 1311. a wheel groove; 1312. and a deviation rectifying sub-wheel.

Detailed Description

In order to facilitate understanding of the present invention, the present invention will be described more fully hereinafter with reference to the accompanying drawings. The preferred embodiments of the present invention are shown in the drawings. The invention may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein. Rather, these embodiments are provided so that this disclosure will be thorough and complete.

It will be understood that when an element is referred to as being "secured to" another element, it can be directly on the other element or intervening elements may also be present. When an element is referred to as being "connected" to another element, it can be directly connected to the other element or intervening elements may also be present.

Unless defined otherwise, all technical and scientific terms used herein have the same meaning as commonly understood by one of ordinary skill in the art to which this invention belongs. The terminology used in the description of the invention herein is for the purpose of describing particular embodiments only and is not intended to be limiting of the invention. As used herein, the term "and/or" includes any and all combinations of one or more of the associated listed items.

As shown in fig. 1, when the panels with different lengths are spliced, the length of the inner panel 17 is smaller than that of the outer panel 18, the inner panel 17 and the outer panel 18 are made into a cylindrical shape, and then the outer panel 18 is sleeved in the inner panel 17, so that the bone positions 171 and 181 of the inner panel are aligned, and then the sewing is performed. In the traditional process of sewing the sleeved inner cut piece 17 and the sleeved outer cut piece 18, the cut pieces need to be manually rotated, and the sewing ends of the cut pieces need to be aligned; at the same time, manual adjustment of the cut pieces is required to make the stitching uniform. Such a sewing process requires a large amount of manual operations, and is cumbersome in operation and inefficient in production.

As shown in fig. 2, 4 and 5, an embodiment of the present invention provides a cut piece splicing and sewing device 10. This cut-parts piece device 10 includes cut-parts plummer 11, sewing mechanism 12, mechanism 13 and workstation 14 of rectifying. The cut-parts plummer 11 can rotate in order to drive the cover locate cut-parts plummer 11 on overlap the interior cut-parts 17, the outer cut-parts 18 rotation that set up. The sewing mechanism 12 is used for piecing the inner panel 17 and the outer panel 18. The deviation rectifying mechanism 13 comprises a deviation rectifying wheel 131 and a deviation rectifying supporting plate 132 which are respectively movably arranged on the worktable 14; the relative positions of the deviation rectifying wheel 131, the deviation rectifying supporting plate 132 and the cut piece bearing table 11 are adjustable. The deviation rectifying wheel 131 can move to abut against the deviation rectifying supporting plate 132.

Cut-parts piece device 10 can carry out the piece to a plurality of different cut-parts of treating of length in this embodiment. In the process of splicing, the shorter cut piece (inner cut piece 17) is sleeved on the cut piece bearing table 11, then the relative position of the deviation-correcting supporting plate 132 and the cut piece bearing table 11 is adjusted, and the longer cut piece (outer cut piece 18) is sleeved on the cut piece bearing table 11, so that the deviation-correcting supporting plate 132 is positioned between the inner cut piece 17 and the outer cut piece 18. The inner panel 17 and the outer panel 18 are sewn through the sewing mechanism 12, and in the sewing process, the outer panel 18 is aligned with the sewing end of the inner panel 17 through the matching action of the deviation rectifying wheel 131 and the deviation rectifying supporting plate 132. When the sewing machine is sewn to the preset position of the overlapped cut pieces formed by the inner cut piece 17 and the outer cut piece 18, the deviation correcting supporting plate 132 is reset, and the sewing mechanism 12 continues to act again to finish the seam splicing. Specifically, in the process of splicing, the deviation rectification wheel 131 presses the outer panel 18 on the deviation rectification supporting plate 132, and the position of the outer panel 18 is adjusted through the action (such as rotation) of the deviation rectification wheel 131, so that the outer panel 18 is aligned with the sewing end of the inner panel 17. In the process of piece, do not need the manual adjustment cut-parts of operating personnel, through the effect of rectifying wheel 131 and the layer board 132 of rectifying can make the sewing end of cut-parts align, can effectively reduce operating personnel's work load like this, improve production efficiency.

In a specific example, the rectification wheel 131 is connected with a fourth driving mechanism 136, and the movement of the rectification wheel 131 is controlled by the fourth driving mechanism, so that the position of the outer panel 18 can be adjusted by the action of the rectification wheel 131, and the alignment of the sewing ends of the inner panel 17 and the outer panel 18 is maintained.

In this embodiment, the fourth driving mechanism 136 is a belt driving mechanism, the belt driving mechanism is connected to the deviation rectifying wheel 131, the deviation rectifying wheel 131 is controlled to rotate along the central axis thereof, and the rotating direction is adjustable, so that the position of the outer panel 18 can be flexibly adjusted, and the sewing ends of the inner panel 17 and the outer panel 18 are kept aligned.

In a specific example, the panel-stitching device 10 further comprises a pusher plate 121; the material pushing plate 121 is movably arranged on the cut piece bearing platform 11 for pushing the spliced inner cut piece 17 and the spliced outer cut piece 18 away from the cut piece bearing platform 11. After the piece is finished, the cut pieces sewed up are pushed out from the cut piece bearing table 11 through the material pushing plate 121, manual work is not needed to take out the cut pieces, and the production efficiency can be further improved. Meanwhile, the human body is prevented from entering the equipment, and the production safety can be improved.

Preferably, the material pushing plate 121 is bent to form a first material pushing arm and a second material pushing arm; when the cut pieces are sleeved on the cut piece bearing table 11, the first pushing arm or the second pushing arm can stretch into the space between the inner cut piece 17 and the cut piece bearing table 11. The material pushing plate 121 is bent to form a first material pushing arm and a second material pushing arm, so that the inner cut piece 17 can be more conveniently isolated from the cut piece bearing table 11.

Further preferably, the included angle between the first pushing arm and the second pushing arm is 90 °. In the splicing process, the pushing arms of the pushing plates 121 parallel to the cut piece bearing table 11 extend into the space between the inner cut piece 17 and the cut piece bearing table 11, so that the inner cut piece 17 is conveniently isolated from the cut piece bearing table 11; after the sewing is completed, the pushing plate 121 acts, and the pushing arm of the pushing plate 121 perpendicular to the cut piece bearing table 11 pushes out the sewn cut piece. It is understood that the included angle between the first pushing arm and the second pushing arm may be other angles, for example, the acute angle between the first pushing arm and the second pushing arm may be 20 °, 30 °, 45 °, 50 °, 60 °, 75 °, and 80 °. Satisfy between one of them material pushing arm can stretch into interior cut-parts 17 and cut-parts plummer 11, accomplish another material pushing arm can push away cut-parts that the piece is good from cut-parts plummer 11 after the piece.

Preferably, the cut piece splicing and sewing device 10 further comprises a driving mechanism (not shown in the figure) connected with the material pushing plate 121, and the material pushing plate 121 is driven by the driving mechanism to move on the cut piece bearing platform 11, so as to complete the action of pushing the processed cut piece from the cut piece bearing platform 11 by the material pushing plate 121.

In one particular example, the sewing mechanism 12 includes a presser foot 122 and a thread breakage device 123; the presser foot 122 is used for pressing the cut piece to be processed sleeved on the cut piece bearing table 11; the thread breaking device 123 is used to break the thread used for the process.

After the inner panel 17 and the outer panel 18 are placed on each other, they are pressed against the panel carrier 11 by the presser foot 122 in preparation for seaming. It is understood that when the inner panel 17 and the outer panel 18 are sewn cylindrical panels, the positions of bones of the inner panel 17 and the outer panel 18 are aligned when they are overlapped, and the presser foot 122 presses the positions of bones of the outer panel 18. The bone positions of the inner cut piece 17 and the outer cut piece 18 are on the same straight line, so that the problems that the bone positions are staggered and the attractiveness and the quality of the clothes are influenced are prevented. After the sewing is finished, the sewing thread used for processing is cut off through the thread cutting device 123, so that the cut-part product after processing is convenient to take down.

As shown in fig. 3, in an embodiment of the present invention, the outer circumference of the wheel 131 is concave to form a plurality of wheel grooves 1311. Entangle the outer peripheral edge of deviation wheel 131 and inwards form a plurality of race 1311 for it is protruding to entangle the outer peripheral edge of deviation wheel 131, is favorable to the reinforcing to entangle the frictional force between wheel 131 and the outer cut-parts 18, conveniently adjusts the position of outer cut-parts 18.

Preferably, a rotatable deviation rectifying sub-wheel 1312 is arranged in each wheel groove 1311; the rectifying sub-wheel 1312 protrudes out of the outer circumference of the rectifying wheel 131. During the seaming process, the outer panel 18 can be kept aligned with the seamed ends of the inner panel 17 by the action of the rectification wheel 131. The deviation-correcting sub-wheel 1312 can further adjust the position of the outer cut piece 18 in the sewing direction, further improve the contact ratio of the outer cut piece 18 and the inner cut piece 17, and further improve the seaming effect.

In one particular example, the deviation correcting mechanism 13 further includes a second drive mechanism 135; the second driving mechanism 135 is connected with the deviation correcting supporting plate 132 to adjust the relative position of the deviation correcting supporting plate 132 and the cut piece bearing table 11. In this embodiment, the second driving mechanism 135 is an air cylinder driving mechanism, and the air cylinder drives the deviation rectifying supporting plate 132 to move, so that the adjusting method is simple and the adjusting efficiency is high.

In a specific example, the cut piece splicing and sewing device 10 further comprises a bearing auxiliary mechanism 15, wherein the bearing auxiliary mechanism 15 comprises a stretching component 151 movably arranged on the workbench 14 and a third driving mechanism 152 connected with the stretching component 151; the third driving mechanism 152 is used for adjusting the relative position of the expanding component 151 and the cut-part bearing table 11. When the cut pieces are sleeved on the cut piece bearing platform 11, the expanding component 151 can stretch into the space between the inner cut piece 17 and the cut piece bearing platform 11.

As shown in fig. 4, when the inner panel 17 is covered on the panel carrier 11, the stretching member 151 can extend between the inner panel 17 and the panel carrier 11. The opening assembly 151 facilitates the more stable sheathing of the inner panel 17 on the panel carrier 11. Further, in the production process, the lengths of the cut pieces to be processed are different, and when the cut pieces to be processed are longer and the circumference of the cross section of the cylindrical cut piece surrounded by the cut pieces is larger than the circumference of the cut piece bearing table 11, the rotation of the cut piece bearing table 11 cannot smoothly drive the cut pieces to complete the rotation action. Through the setting that bears complementary unit 15, when cut-parts are longer, adjust and strut the position of subassembly 151 on the workstation, the cover that makes cut-parts can be stable is established on cut-parts plummer 11, and then drives smoothly through the rotation of cut-parts plummer 11 and treats that the cut-parts of processing accomplish the rotation action.

In a specific example, the panel splicing and sewing device 10 further comprises a position detecting device 16, and the position detecting device 16 is arranged on the panel carrier 11 for detecting whether the sewing ends of the inner panel 17 and the outer panel 18 are aligned. It is necessary to keep the seamed ends of the inner and outer panels 17, 18 aligned during the seaming process. In this embodiment, the position of the inner panel 17 is fixed, and the position of the outer panel 18 is adjusted to keep the inner panel 17 aligned with the sewn ends of the outer panel 18. The position detection means 16 may be a photo sensor, by which the position detection means 16 determines the position of the outer panel 18. The photoelectric sensor can detect the position of the sewing end of the outer panel 18, and when the position of the sewing end of the outer panel 18 is detected to be not satisfied (namely, the sewing end of the outer panel 18 is not aligned with the sewing end of the inner panel 17), the position of the outer panel 18 is adjusted by the rotation of the rectification wheel 131, so that the sewing end of the outer panel 18 is aligned with the sewing end of the inner panel 17.

As shown in fig. 5, in a specific example, the deviation correcting mechanism 13 further includes a link 133 and a first driving mechanism 134. The connecting rod 133 is rotatably mounted on the worktable 14, one end of the connecting rod 133 is connected with the deviation rectifying wheel 131, and the other end of the connecting rod 133 is connected with the first driving mechanism 134; the relative position of the rectification wheel 131 and the cut piece bearing table 11 is adjusted by the first driving mechanism 134 through the connecting rod 133.

In this embodiment, after the piece is sewed up, the action of the first driving mechanism 134 drives the connecting rod 133 to move, so as to lift up the deviation rectifying wheel 131, thereby facilitating the taking out of the sewed cut pieces. In the sewing process, the first driving mechanism 134 operates to lower the deviation rectifying wheel 131, so as to press the outer cut piece 18 on the deviation rectifying supporting plate 132, thereby completing the deviation rectifying action. Preferably, during the sewing process, the first driving mechanism 134 is lifted, and the deviation rectifying wheel 131 is lowered by gravity to press the outer panel 18 on the deviation rectifying support plate 132, so as to complete the deviation rectifying action.

The utility model discloses an embodiment still provides a cut-parts piece method, adopts above-mentioned cut-parts piece device 10, and the piece method includes following step:

the inner cut piece 17 is sleeved on the cut piece bearing table 11;

adjusting the relative position of the deviation-rectifying supporting plate 132 and the cut piece bearing table 11, sleeving the outer cut piece 18 on the cut piece bearing table 11 and enabling the deviation-rectifying supporting plate 132 to be positioned between the inner cut piece 17 and the outer cut piece 18; the inner panel 17 forms an overlapping panel with the outer panel 18;

adjusting the relative position of the deviation rectifying wheel 131 and the cut piece bearing table 11 to ensure that the deviation rectifying wheel 131 presses the outer cut piece 18 on the deviation rectifying supporting plate 132; the rectification wheel 131 and the rectification supporting plate 132 cooperate to align the sewing ends of the outer cut piece 18 and the inner cut piece 17;

when the sewing mechanism 12 is sewn to the preset position of the overlapped cut pieces, the deviation correcting supporting plate 132 is reset, and the sewing mechanism 12 continues to sew.

In this embodiment, the inner panel 17 is sleeved on the panel bearing table 11, and the expanding component 151 extends between the inner panel 17 and the panel bearing table 11. Then the outer cut piece 18 is sleeved on the cut piece bearing platform 11, the deviation correcting supporting plate 132 is positioned between the inner cut piece 17 and the outer cut piece 18, meanwhile, the bone position 171 of the inner cut piece is aligned with the bone position 181 of the outer cut piece, and the bone position 181 of the outer cut piece is pressed by the presser foot 122. In the splicing and sewing process, the cut-parts bearing table 11 rotates to drive the inner cut-parts 17 and the outer cut-parts 18 to rotate, the internal cut-parts 17 and the outer cut-parts 18 are spliced by the sewing mechanism 12, the positions of the outer cut-parts 18 are adjusted through the cooperation of the deviation rectifying wheels 131 and the deviation rectifying supporting plates 132, and the sewing ends of the outer cut-parts 18 are kept aligned with the sewing ends of the inner cut-parts 17. When the sewing mechanism 12 is sewn to a preset position (for example, to 80% -90% of the length of the overlapped cut pieces), the deviation correcting supporting plate 132 is reset, and the sewing mechanism 12 continues to sew, completing the edge joint of the inner cut piece 17 and the outer cut piece 18. The sewn cut pieces are pushed out by the material pushing plate 121, and the sewing lines for processing are broken by the line breaking device 123.

The cut piece splicing method is simple to operate, and only the cut piece is manually sleeved on the cut piece bearing table to be prepared for sewing. In the process of splicing, the cutting pieces do not need to be manually adjusted, the workload of operators can be effectively reduced, and the production efficiency is improved.

The technical features of the embodiments described above may be arbitrarily combined, and for the sake of brevity, all possible combinations of the technical features in the embodiments described above are not described, but should be considered as being within the scope of the present specification as long as there is no contradiction between the combinations of the technical features.

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

Claims (10)

1. The utility model provides a cut-parts piece device which characterized in that: comprises a cut piece bearing platform, a sewing mechanism, a deviation correcting mechanism and a workbench;

the cutting piece bearing table can rotate to drive the inner cutting piece and the outer cutting piece which are sleeved on the cutting piece bearing table and are arranged in an overlapped mode to rotate;

the sewing mechanism is used for splicing the inner cut piece and the outer cut piece;

the deviation rectifying mechanism comprises a deviation rectifying wheel and a deviation rectifying supporting plate which are respectively and movably arranged on the workbench; the relative positions of the deviation rectifying wheel, the deviation rectifying supporting plate and the cut piece bearing table are adjustable; the deviation rectifying wheel can move to be abutted to the deviation rectifying supporting plate.

2. The panel splicing and sewing device of claim 1, wherein: the outer circumference of the deviation rectifying wheel is concave inwards to form a plurality of wheel grooves.

3. The panel splicing and sewing device of claim 2, wherein: each wheel groove is internally provided with a rotatable deviation rectifying sub-wheel; the deviation rectifying sub-wheel protrudes out of the outer periphery of the deviation rectifying wheel.

4. The panel splicing and sewing device of claim 1, wherein: the deviation correcting mechanism further comprises a connecting rod and a first driving mechanism;

the connecting rod is rotatably arranged on the workbench, one end of the connecting rod is connected with the deviation rectifying wheel, and the other end of the connecting rod is connected with the first driving mechanism; the first driving mechanism adjusts the relative position of the deviation rectifying wheel and the cut piece bearing table through the connecting rod.

5. The panel splicing and sewing device of claim 1, wherein: the deviation correcting mechanism further comprises a second driving mechanism; the second driving mechanism is connected with the deviation rectifying supporting plate to adjust the relative position of the deviation rectifying supporting plate and the cut piece bearing table.

6. A panel splicing and sewing device according to any one of claims 1 to 5, characterized in that: the device also comprises a material pushing plate; the scraping wings are movably arranged on the cut piece bearing table to complete the splicing of the inner cut piece and the outer cut piece.

7. The panel splicing and sewing device of claim 6, wherein: the material pushing plate is bent to form a first material pushing arm and a second material pushing arm; when the cut-parts are sleeved on the cut-parts bearing table, the first pushing arm or the second pushing arm can stretch into the inner cut-parts and between the cut-parts bearing table.

8. The panel splicing and sewing device of claim 7, wherein: the included angle between the first material pushing arm and the second material pushing arm is 90 degrees.

9. A panel splicing and sewing device according to any one of claims 1 to 5, characterized in that: the supporting mechanism comprises a supporting component movably arranged on the workbench and a third driving mechanism connected with the supporting component; the third driving mechanism is used for adjusting the relative position of the spreading assembly and the cut piece bearing table;

when the cut-parts are sleeved on the cut-parts bearing table, the opening component can stretch into the inner cut-parts and between the cut-parts bearing table.

10. A panel splicing and sewing device according to any one of claims 1 to 5, characterized in that: still include position detection device, position detection device locates in order to be used for detecting on the cut-parts plummer interior cut-parts the sewing end of outer cut-parts is whether to align.

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