CN117485720B - Anti-wrinkling pre-storing box for textile manufacturing - Google Patents

Abstract

The invention relates to the technical field of textiles and discloses an anti-wrinkling pre-storing box for textile manufacture, which comprises a box body and base plates stacked in the box body, wherein a plurality of arc grooves are formed on two sides of the upper surface of each base plate, a plurality of arc protrusions are formed on two sides of the lower surface of each base plate, two upper and lower adjacent base plates are nested in the arc grooves in a one-to-one correspondence manner through the arc protrusions to form positioning and a gap for placing textiles is formed between the two base plates; the flattening structure is arranged right above the box body; the flattening structure is used for conveying the empty pad plate to the cutting surface of the rotary cutting knife or the laser cutting knife so that the textile is directly paved on the empty pad plate after cutting. The invention adopts the mode that the base plates are vertically stacked in the box body, the base plates cannot slide transversely, and the invention also adopts the mode that the arc-shaped protrusions and the arc-shaped grooves are meshed between the adjacent base plates so as to form positioning and a gap for placing textiles is formed between the two base plates.

Description

Anti-wrinkling pre-storing box for textile manufacturing

Technical Field

The invention relates to the technical field of textiles, in particular to an anti-wrinkling pre-storage box for textile manufacturing.

Background

Textile is a product formed by processing and weaving textile fibers, and is divided into two main types of woven cloth and knitted cloth, china is one of the earliest countries in the world for producing textile, and the correct stacking method of textile is selected to be favorable for ventilation and fire prevention. When the original textile is stored, the textiles are piled together, and wrinkles are easily generated, so that the appearance of the textile is affected, and the selling or processing of the textile is not facilitated.

In order to solve the above problems, a partition plate is generally used in the prior art for separation. For example, chinese patent with publication number CN219506479U discloses a wrinkle-proof pre-storing box for textile manufacture, comprising a housing assembly and a connecting assembly, wherein the housing assembly comprises a box body, a push-pull box and an upper cover, the push-pull box is arranged in the box body and is in sliding connection with the box body, the upper cover is arranged on the upper surface of the box body, a pull groove is formed in the front surface of the push-pull box, the pull groove is fixedly connected with the push-pull box, and a first vent hole is formed in one end of the push-pull box, which is close to the box body; set up a plurality of push-and-pull plates in the box, with the fabrics tiling on the push-and-pull plate, the fabrics twine together when avoiding the box to remove, and the pressure between push-and-pull plate and the push-and-pull plate flattens the fabrics simultaneously, makes things convenient for the storage of fabrics, places the drier in the push-and-pull box to ventilate through first air vent and second air vent, avoid the fabrics to go moldy in the box, make things convenient for the storage of fabrics.

However, the above patent has some problems:

1) The artificial laying is required to be carried out on the push-pull plate, and the artificial leveling laying consumes more manpower and has higher difficulty;

2) When the box body shakes, the push-pull plate is easy to slide out due to the sliding installation.

Disclosure of Invention

The present invention is directed to solving at least one of the technical problems of the related art described above to some extent.

Therefore, the embodiment of the invention provides an anti-wrinkling pre-storing box for textile manufacture, which comprises a box body and base plates stacked in the box body, wherein a plurality of arc grooves are formed in two sides of the upper surface of each base plate, a plurality of arc protrusions are formed in two sides of the lower surface of each base plate, and two upper and lower adjacent base plates are nested in the arc grooves in a one-to-one correspondence manner through the arc protrusions to form positioning and a gap for placing textiles is formed between the two base plates;

the flattening structure is arranged right above the box body; the flattening structure is used for conveying the empty backing plate to the cutting surface of the rotary cutting knife or the laser cutting knife so that the textile is directly paved on the empty backing plate after cutting.

Further, a plurality of arc-shaped sub-grooves with different radians are arranged around each arc-shaped groove side by side.

Further, the textile winding machine also comprises a workbench which is arranged above the box body in parallel, wherein one end of the workbench is provided with an unwinding mechanism for releasing the textile winding, and the other end of the workbench is provided with a winding mechanism for collecting waste materials after textile cutting.

Further, unreeling mechanism includes the roller one that sets up through the slope of support one, the both ends of roller one all are equipped with pivot one, the top of support one is equipped with the open slot, every the bearing of pivot one is all installed in the open slot, install roller two through support two on the support one.

Further, the winding mechanism comprises a roller III which is obliquely arranged through a bracket III, two ends of the roller III are respectively provided with a rotating shaft II, a bearing of each rotating shaft II is arranged on the bracket III, a driving structure for driving any rotating shaft II is arranged on the bracket III, and the roller IV is arranged on the bracket III through a bracket IV;

the fourth roller and the second roller are used for being matched to horizontally press the textile on the upper surface of the workbench.

Further, the flattening structure comprises a mounting plate fixed relative to the workbench, two sides of the mounting plate are connected with sliding grooves, a movable bottom plate is arranged between the two sliding grooves, two side edges of the movable bottom plate are respectively and slidably nested into the two sliding grooves, and a plurality of telescopic cylinders I are connected between the movable bottom plate and the mounting plate; the movable bottom plate is provided with a movable upper plate in parallel, three of four vertexes of the upper surface of the movable bottom plate are respectively provided with a linear telescopic rod, the other vertex is hinged with a telescopic cylinder II, the top end of each linear telescopic rod and the top end of the telescopic cylinder II are respectively nested with a rotating rod through a allowance hole, and each rotating rod is arranged on the movable upper plate;

the workbench is provided with a through groove, a positioning arc hole is formed in the movable upper plate and opposite to the side edge of the through groove, a mounting hole groove is formed in the side wall of the through groove, a calibration column is movably mounted in the mounting hole groove through an elastic piece, and the calibration column is matched with the positioning arc hole in shape so as to be nested in the positioning arc hole.

Further, a cavity is formed in the movable upper plate, a plurality of positioning arc recesses are formed in the movable upper plate and used for nesting the arc protrusions in a one-to-one correspondence mode, the cavity is connected with a vacuum pump, and the cavity is connected with the bottom end of each positioning arc recess through a channel.

Further, limit areas are arranged on two sides of the base plate; bending areas for adapting to the limiting areas are arranged on two sides of the through groove, and pneumatic clamps are arranged in the bending areas; and bending parts for adapting to the limiting areas are also arranged on two sides of the box body.

Compared with the prior art, the invention has the beneficial effects that:

firstly, in order to solve the problem that a backing plate of a textile (namely a push-pull plate in the background art) is easy to slide transversely in the prior art, the backing plate is vertically stacked in a box body and cannot slide transversely, and the invention also adopts the way that the arc-shaped protrusions and the arc-shaped grooves are meshed between the adjacent backing plates to form positioning and a gap for placing the textile is formed between the adjacent backing plates;

secondly, in order to solve the problem that the textile in the prior art needs to be manually paved on the backing plate, the backing plate can be directly used as a part of a cutting surface of a rotary cutting knife or a laser cutting knife through a flattening structure, so that the textile is directly paved by the flattening structure to be cut and placed on the backing plate, and the two steps of operations are fused into one step (normally, the textile is firstly cut and then is transported and stored).

Drawings

FIG. 1 is a schematic view of the overall structure of the present invention at an angle;

FIG. 2 is a schematic view of the overall structure of another angle of the present invention;

FIG. 3 is a schematic diagram of the connection of the mobile top plate and the mobile bottom plate of the present invention;

FIG. 4 is a top view of the overall structure of the present invention;

FIG. 5 is a cross-sectional view of A-A of FIG. 4;

FIG. 6 is a cross-sectional view of a shim plate of the present invention having arcuate grooves therein;

FIG. 7 is a schematic representation of the stacking of adjacent mats according to the invention.

Reference numerals:

1. a case; 2. a backing plate; 3. an arc-shaped groove; 4. arc-shaped bulges; 5. arc-shaped sub-grooves; 6. a flattening structure; 7. a work table; 8. an unreeling mechanism; 9. a winding mechanism; 10. a first bracket; 11. a first roller; 12. a first rotating shaft; 13. an open slot; 14. a second bracket; 15. a second roller; 16. a third bracket; 17. a third roller; 18. a second rotating shaft; 19. a bracket IV; 20. a fourth roller; 21. a mounting plate; 22. a chute; 23. a movable bottom plate; 24. a telescopic cylinder I; 25. moving the upper plate; 26. a linear telescopic rod; 27. a telescopic cylinder II; 28. a remainder hole; 29. a rotating rod; 30. penetrating a groove; 31. positioning an arc hole; 32. a mounting hole groove; 33. an elastic member; 34. calibrating the column; 35. a cavity; 36. a channel; 37. a limit area; 38. a bending region; 39. a bending part; 40. and (5) a pneumatic clamp.

Detailed Description

The following description of the embodiments of the present invention will be made apparent and fully in view of the accompanying drawings, in which some, but not all embodiments of the invention are shown.

As shown in fig. 1 to 7, the present embodiment provides a wrinkle-preventing pre-storing box for textile manufacturing, which comprises a box body 1 and backing plates 2 stacked in the box body 1, wherein two sides of the upper surface of each backing plate 2 are respectively provided with a plurality of arc-shaped grooves 3, two sides of the lower surface of each backing plate 2 are respectively provided with a plurality of arc-shaped protrusions 4, and two upper and lower adjacent backing plates 2 are nested in the arc-shaped grooves 3 in a one-to-one correspondence manner through the arc-shaped protrusions 4 so as to form positioning and a gap for placing textiles between the two backing plates; the box body 1 is provided with a flattening structure 6; the flattening structure 6 is used to transport the empty mat 2 onto the cutting surface of a rotating cutting blade or laser cutting blade so that the textile product after cutting is laid directly on the empty mat 2.

In order to solve the problem that the backing plate 2 (i.e. the push-pull plate in the background art) of the textile in the prior art is easy to slide transversely, the backing plate 2 is vertically stacked in the box body 1, the backing plate 2 cannot slide transversely, and the invention also adopts the way that the arc-shaped protrusions 4 and the arc-shaped grooves 3 are meshed between the adjacent backing plates 2 to form positioning and a gap for placing the textile is formed between the two.

It should be noted in particular that the length of the cut textile product may be the same as the backing plate 2, while the width of the cut textile product is much smaller than the backing plate 2, so that the arcuate grooves 3 on both sides of the backing plate 2 are exposed.

In order to solve the problem that the textile in the prior art needs to be manually paved on the base plate 2, the base plate 2 can be directly used as a part of a cutting surface of a rotary cutting knife or a laser cutting knife through the flattening structure 6 (note that the material of the base plate 2 can be consistent with that of a base plate of a common cutter device, in fact, the base plate 2 can also be made of hard plastic, even if a small amount of nicks are left on the hard plastic by the cutting knife, the use of the base plate 2 is not hindered), so that the base plate 2 is directly paved and cut by the flattening structure 6 and placed on the base plate 2, and two steps of operations are fused into one step (normally, cutting is carried out first and then transferring and storing).

The invention also comprises a workbench 7 which is arranged above the box body 1 in parallel, one end of the workbench 7 is provided with an unreeling mechanism 8 for releasing the textile coil, and the other end of the workbench 7 is provided with a reeling mechanism 9 for collecting waste materials after textile cutting. The unreeling mechanism 8 comprises a first roller 11 which is obliquely arranged through a first bracket 10, two ends of the first roller 11 are respectively provided with a first rotating shaft 12, the top end of the first bracket 10 is provided with an open slot 13, a bearing of each first rotating shaft 12 is arranged in the open slot 13, and a second roller 15 is arranged on the first bracket 10 through a second bracket 14. The winding mechanism 9 comprises a third roller 17 obliquely arranged through a third bracket 16, two ends of the third roller 17 are respectively provided with a second rotating shaft 18, a bearing of each second rotating shaft 18 is arranged on the third bracket 16, a driving structure for driving any second rotating shaft 18 is arranged on the third bracket 16, and a fourth roller 20 is arranged on the third bracket 16 through a fourth bracket 19; the fourth roller 20 and the second roller 15 are used for being matched with each other to horizontally press the textile on the upper surface of the workbench 7.

The flattening structure 6 comprises an installation plate 21 fixed relative to the workbench 7, two sides of the installation plate 21 are connected with sliding grooves 22, a movable bottom plate 23 is arranged between the two sliding grooves 22, two side edges of the movable bottom plate 23 are respectively and slidably nested into the two sliding grooves 22, and a plurality of telescopic cylinders I24 are connected between the movable bottom plate 23 and the installation plate 21; the movable bottom plate 23 is provided with a movable upper plate 25 in parallel, three of four vertexes of the upper surface of the movable bottom plate 23 are respectively provided with a linear telescopic rod 26, the other vertex is hinged with a telescopic cylinder II 27, the top end of each linear telescopic rod 26 and the top end of the telescopic cylinder II 27 are respectively nested with a rotating rod 29 through a residual hole 28, and each rotating rod 29 is arranged on the movable upper plate 25; the workbench 7 is provided with a through groove 30, the side edge of the movable upper plate 25, which is opposite to the through groove 30, is provided with a positioning arc hole 31, the side wall of the through groove 30 is provided with a mounting hole groove 32, a calibration column 34 is movably mounted in the mounting hole groove 32 through an elastic piece 33, and the calibration column 34 is matched with the positioning arc hole 31 in shape so as to be nested in the positioning arc hole.

Firstly, detaching and taking down a roller I11 from an opening groove 13 of a bracket I10, sleeving a textile coil coiled by a textile coiling machine on the roller I11, and then installing the roller I11 sleeved with the textile coil back to the bracket I10; the outer end of the textile roll is then passed through the second and fourth rollers 15, 20 until the outer end is secured to the third roller 17, and the third roller 17 is then wound up by a drive mechanism, typically a servo motor, such that the portion of the textile roll between the second and fourth rollers 15, 20 is stretched and applied to the table 7. Limiting areas 37 are arranged on two sides of the backing plate 2; bending areas 38 for adapting to the limiting areas 37 are arranged on two sides of the through groove 30, and the bending areas 38 are provided with pneumatic clamps 40; the two sides of the box 1 are also provided with bending parts 39 for adapting to the limiting areas 37.

Then, the pad 2 is placed on the movable upper plate 25, and then the movable upper plate 25 is extended by the telescopic cylinder one 24 on the mounting plate 21, so that the movable upper plate 25 is driven by the movable bottom plate 23 to gradually move right below the workbench 7 (note that in the initial state, the movable bottom plate 23 and the movable upper plate 25 are basically in an overlapping state), until the movable upper plate 25 is opposite to the through slot 30 of the workbench 7, the telescopic cylinder two 27 is driven to extend, so that the distance between the movable upper plate 25 and the movable bottom plate 23 is gradually increased, then under the limitation of three linear telescopic rods 26 (generally formed by nesting of a plurality of sections of sliding cylinders), the movable upper plate 25 can move upwards on the basis of the movable bottom plate 23, finally until the side edge of the movable upper plate 25 is opposite to the side edge of the through slot 30, because the cross-sectional area of the movable upper plate 25 is larger, the multi-point support is required to move upwards and downwards, but the multi-point support is difficult to keep on the same horizontal plane, and therefore, in the invention, by setting the residual holes 28, each rotating rod 29 can move to a certain extent, so that the movable upper plate 25 can be slightly displaced from the residual holes 28, and the positioning holes 31 can be aligned with the four arc holes 31, and the positioning columns 31 can be aligned with the arc positioning columns 31, and the arc positioning columns can be aligned with the arc positioning columns 31.

At this time, the movable upper plate 25 is attached just under the portion of the textile roll between the second roller 15 and the fourth roller 20, and then the textile on the movable upper plate 25 and the backing plate 2 is cut by rotating the cutter or the laser cutter (note that the length of the textile cut is obviously smaller than the length of the backing plate 2 at this place, but the width of the textile cut is not only smaller than the width of the backing plate 2 at this place, but also greater than the width of the backing plate 2), so that the textile roll is left with the cloth on both sides in the width direction after the cut, thereby ensuring that the textile roll is continuously wound, facilitating the continuous winding by the winding mechanism 9, and improving the automation capability of the apparatus.

After finishing textile cutting on the base plate 2, the movable upper plate 25 moves downwards (because the positioning arc hole 31 is meshed with the calibration column 34 in an arc shape, the elastic piece 33 is compressed by the force transmitted by extrusion at the moment and does not affect the sliding downwards), then when the base plate 2 enters the through groove 30, the base plate 2 is clamped and fixed by the most protruding limiting areas 37 of the two sides clamping base plate 2 through the pneumatic clamps 40 on the bending areas 38, the two sides of the movable upper plate 25 do not have the protruding positions, so the movable upper plate 25 continues to slide downwards to finish the separation from the base plate 2 until being overlapped with the movable base plate 23, then the movable upper plate is contracted by the telescopic cylinder I24, so that the base plate 2 is far away from the position under the workbench 7, a space is reserved for entering the box 1, the base plate 2 is slowly lowered into the box 1 generally through the manual auxiliary base plate 2, the vacuum chuck can also be adsorbed in the limiting areas 37, and then the lifting of the vacuum chuck is controlled through the structure such as an electric telescopic rod.

In order to further solve the problem that the difficulty of accurately placing the backing plate 2 on the movable upper plate 25 is large, a cavity 35 is arranged in the movable upper plate 25, a plurality of positioning arc recesses are arranged on the movable upper plate 25 and are used for nesting the arc-shaped bulges 4 in a one-to-one correspondence manner, the cavity 35 is connected with a vacuum pump, and the cavity 35 is connected with the bottom end of each positioning arc recess through a channel 36.

In this way, the pad 2 can be initially guided and positioned by the positioning arc recess, and then negative pressure is generated to the cavity 35 by the vacuum pump, so that the suction force is maximum when the pad 2 is completely aligned with the movable upper plate 25 during manual movement of the pad 2, thereby preventing manual continued movement, and playing a role in helping calibration (note that the vacuum pump needs to be turned off when the pad 2 is separated from the movable upper plate 25 or when the movable upper plate 25 is lowered).

In this embodiment, the limiting area 37 is disposed on the backing plate 2, so that the backing plate cannot move transversely, while in other embodiments, a plurality of arc-shaped sub-grooves 5 with different radians may be disposed side by side around each arc-shaped groove 3, as shown in fig. 7, at this time, some slight transverse movement may be performed between the adjacent backing plates 2, so that the adjustment of the spacing may be performed.

In the description of the present invention, it should be noted that, unless explicitly specified and limited otherwise, the terms "mounted," "connected," and "connected" are to be construed broadly, and may be either fixedly connected, detachably connected, or integrally connected, for example; can be mechanically or electrically connected; can be directly connected or indirectly connected through an intermediate medium, and can be communication between two elements. The specific meaning of the above terms in the present invention will be understood in specific cases by those of ordinary skill in the art.

Claims (4)

1. The anti-wrinkling pre-storing box for textile manufacture comprises a box body (1) and base plates (2) stacked in the box body (1), and is characterized in that a plurality of arc grooves (3) are formed in two sides of the upper surface of each base plate (2), a plurality of arc protrusions (4) are formed in two sides of the lower surface of each base plate (2), and two upper and lower adjacent base plates (2) are nested in the arc grooves (3) in a one-to-one correspondence manner through the arc protrusions (4) to form a positioning gap for placing textiles;

the box body also comprises a flattening structure (6) arranged right above the box body (1); the flattening structure (6) is used for conveying the empty backing plate (2) to a cutting surface of a rotary cutting knife or a laser cutting knife so that textiles are directly paved on the empty backing plate (2) after cutting;

the textile fabric winding and unwinding device is characterized by further comprising a workbench (7) arranged above the box body (1) in parallel, wherein an unwinding mechanism (8) for releasing the textile fabric winding is arranged at one end of the workbench (7), and a winding mechanism (9) for collecting waste materials after textile fabric cutting is arranged at the other end of the workbench (7);

the flattening structure (6) comprises an installation plate (21) fixed at the opposite position to the workbench (7), two sides of the installation plate (21) are connected with sliding grooves (22), a movable bottom plate (23) is arranged between the two sliding grooves (22), two side edges of the movable bottom plate (23) are respectively and slidably nested into the two sliding grooves (22), and a plurality of telescopic cylinders I (24) are connected between the movable bottom plate (23) and the installation plate (21); a movable upper plate (25) is arranged on the movable bottom plate (23) in parallel, three of four vertexes of the upper surface of the movable bottom plate (23) are provided with linear telescopic rods (26), the other vertex is hinged with a telescopic cylinder II (27), the top end of each linear telescopic rod (26) and the top end of the telescopic cylinder II (27) are nested with a rotating rod (29) through a residual hole (28), and each rotating rod (29) is arranged on the movable upper plate (25);

a through groove (30) is formed in the workbench (7), a positioning arc hole (31) is formed in the movable upper plate (25) and opposite to the side edge of the through groove (30), a mounting hole groove (32) is formed in the side wall of the through groove (30), a calibration column (34) is movably mounted in the mounting hole groove (32) through an elastic piece (33), and the calibration column (34) is matched with the positioning arc hole (31) in shape so as to be nested in the positioning arc hole;

a cavity (35) is arranged in the movable upper plate (25), a plurality of positioning arc recesses are arranged on the movable upper plate (25) and are used for nesting the arc-shaped bulges (4) in a one-to-one correspondence manner, the cavity (35) is connected with a vacuum pump, and the cavity (35) is connected with the bottom end of each positioning arc recess through a channel (36);

limiting areas (37) are arranged on two sides of the base plate (2); bending areas (38) for adapting to the limiting areas (37) are arranged on two sides of the through groove (30), and the bending areas (38) are provided with pneumatic clamps (40); the two sides of the box body (1) are also provided with bending parts (39) which are used for adapting to the limiting areas (37).

2. The anti-wrinkling pre-storage box for textile manufacturing according to claim 1, wherein a plurality of arc sub-grooves (5) with different radians are arranged side by side around each arc groove (3).

3. The wrinkle-preventing pre-storage box for textile manufacturing according to claim 1, wherein the unreeling mechanism (8) comprises a first roller (11) obliquely arranged through a first bracket (10), two ends of the first roller (11) are respectively provided with a first rotating shaft (12), the top end of the first bracket (10) is provided with an open slot (13), a bearing of each first rotating shaft (12) is arranged in the open slot (13), and a second roller (15) is arranged on the first bracket (10) through a second bracket (14).

4. A wrinkle-preventing pre-storage box for textile manufacture according to claim 3, wherein the winding mechanism (9) comprises a roller three (17) obliquely arranged through a bracket three (16), two ends of the roller three (17) are respectively provided with a rotating shaft two (18), a bearing of each rotating shaft two (18) is arranged on the bracket three (16), a driving structure for driving any rotating shaft two (18) is arranged on the bracket three (16), and a roller four (20) is arranged on the bracket three (16) through a bracket four (19);

the fourth roller (20) and the second roller (15) are used for being matched with each other to horizontally press the textile on the upper surface of the workbench (7).