CN110607681A - Full-automatic multilayer gauze covering, cutting and filling equipment - Google Patents

Abstract

The application discloses full-automatic multilayer gauze covers closes dicing filler equipment includes: a pan feeding mechanism for with the range upon range of pan feeding in a plurality of materials area for to a plurality of materials area of range upon range of pan feeding cut along longitudinal direction and form the indulging of a plurality of material strips and cut out the mechanism, be used for with the fixed length feeding mechanism of a plurality of material strip fixed length outputs, hold in the palm material mechanism, it includes: the material conveying device comprises at least two material supporting platforms used for supporting the plurality of material strips with fixed length output, a pressing adsorption and transfer mechanism used for pressing the plurality of material strips on the material supporting platforms, a transverse cutting mechanism used for cutting the plurality of pressed material strips along a transverse cutting channel to form material blocks, and the pressing adsorption and transfer mechanism is further used for adsorbing the plurality of material blocks and transferring the material blocks to a conveying line along the longitudinal direction. When the device is used for producing the gauze pieces, all the procedures are mutually connected, the procedures do not need to be rotated, the labor cost can be reduced, and the production efficiency is obviously improved.

Description

Full-automatic multilayer gauze covering, cutting and filling equipment

Technical Field

The application relates to the technical field of gauze piece production, in particular to full-automatic multilayer gauze covering and cutting packing equipment.

Background

In the traditional gauze block manufacturing process, single-layer gauzes are mostly stacked to form multiple layers of gauzes through a cloth spreading machine or in a manual mode, then the gauze blocks are manually cut into blocks in a cutting station, and the gauze blocks are conveyed to a plane packing machine for carrying out slicing, filling and packing. Therefore, the traditional process has more procedures, needs a large amount of manpower to complete, and has low efficiency and high labor cost.

Disclosure of Invention

The application aims at providing a full-automatic multilayer gauze covers closes stripping and slicing filler equipment to improve gauze piece production efficiency.

A full-automatic multilayer gauze covers closes dicing filler equipment includes:

the feeding mechanism is used for stacking and feeding a plurality of material belts;

the longitudinal cutting mechanism is used for cutting the plurality of material belts which are stacked and fed with materials along the longitudinal direction to form a plurality of material strips;

the fixed-length feeding mechanism is used for outputting the plurality of material strips in a fixed length manner;

hold in the palm material mechanism, it includes: the material supporting platforms are sequentially arranged along the longitudinal direction and used for supporting the plurality of material strips which are output in a fixed length mode; at least two transverse cutting channels are formed between the material supporting platform close to the fixed-length feeding mechanism and between two adjacent material supporting platforms;

the pressing adsorption transfer mechanism is used for pressing the plurality of material strips on the material supporting platform;

horizontal cutting mechanism, it includes: the horizontal cutting and traversing unit is used for driving the horizontal cutting and traversing units to respectively reciprocate along the at least two horizontal cutting channels, and the at least two horizontal cutting units are used for cutting the plurality of strips pressed on the material supporting platform to form a plurality of material blocks; the pressing, adsorbing and transferring mechanism is further used for adsorbing and transferring the blocks to a conveying line along the longitudinal direction.

Further, full-automatic multilayer gauze laminating dicing filler equipment, wherein, still include: the setting is in pan feeding mechanism with indulge first buffer memory mechanism between the cutting mechanism, first buffer memory mechanism includes: the material roller is crossed to a plurality of first, the axial direction of first material roller of crossing is the transverse direction, a plurality of first material rollers of crossing are parallel to each other, and the dislocation is arranged.

Further, full-automatic multilayer gauze laminating dicing filler equipment, wherein, pan feeding mechanism includes: a plurality of units that unreel to and pan feeding traction unit, each unreel the unit and all include: the unwinding shaft and the unwinding shaft power roller are parallel to each other, and the unwinding shaft is used for rotating around the axial lead of the unwinding shaft so as to unwind and discharge the material belt; the unwinding shaft power roller is used for pressing the coiled material raw material wound on the unwinding shaft and rotating around the axis of the unwinding shaft power roller so as to drive the unwinding shaft to rotate; the pan feeding traction unit includes: the axial direction of the feeding traction rollers is the transverse direction, and the feeding traction rollers are used for outputting movement along the longitudinal positive direction so as to draw the multiple material belts output in a laminated manner; the rotational linear speed of the feeding traction roller is greater than that of the unreeling shaft power roller.

Further, full-automatic multilayer gauze laminating dicing filler equipment, wherein indulge cutting mechanism and include: a plurality of longitudinal cutting units and a longitudinal cutting traction unit; the longitudinal cutting unit is used for cutting the plurality of material belts which are stacked and fed to form a plurality of material strips, and the longitudinal cutting traction unit is used for drawing and feeding the plurality of material strips to the fixed-length feeding mechanism; the slitting unit includes: the longitudinal cutting device comprises a longitudinal cutting driving wheel, at least one longitudinal cutting driven wheel, a longitudinal cutting steel belt cutter and a longitudinal cutting driving motor, wherein the width direction of the longitudinal cutting steel belt cutter, the axial direction of the longitudinal cutting driving wheel and the axial direction of the longitudinal cutting driven wheel are both longitudinal directions, the centers of the longitudinal cutting driving wheel and the longitudinal cutting driven wheel are in the same plane, the plane is perpendicular to the plurality of stacked material belts, the longitudinal cutting steel belt cutter is wound on the longitudinal cutting driving wheel and the longitudinal cutting driven wheel, the longitudinal cutting steel belt cutter is provided with a cutting edge facing the material belt conveying direction, and the longitudinal cutting driving motor is used for driving the longitudinal cutting driving wheel to rotate so as to drive the longitudinal cutting driven wheel to rotate; the rip cutting traction unit includes: a pair of longitudinal cutting drawing rollers.

Further, full-automatic multilayer gauze laminating dicing filler equipment, wherein, equipment still includes: the setting is in indulge and cut out the draw unit with second buffer memory mechanism between the fixed length pan feeding mechanism, second buffer memory mechanism includes: the axial direction is the second of horizontal direction and passes the material roller, the second is passed the material roller and can be followed the up-and-down swing, but can not rotate.

Further, full-automatic multilayer gauze laminating dicing filler equipment, wherein, the horizontal cutting unit includes: the horizontal cutting device comprises a horizontal cutting fixing frame, a horizontal cutting driving wheel, at least one horizontal cutting driven wheel, a horizontal cutting steel band knife and a horizontal cutting driving motor, wherein the horizontal cutting driving wheel is arranged on the horizontal cutting fixing frame; the width direction of the transverse cutting steel band knife, the axial direction of the transverse cutting driving wheel and the axial direction of the transverse cutting driven wheel are all transverse directions; the centers of the transverse cutting driving wheel and the transverse cutting driven wheel are in the same plane, and the plane is vertical to the material belt; the transverse steel belt cutter is wound on the transverse driving wheel and the at least one transverse driven wheel and is provided with a blade facing the transverse direction of the material belt; the horizontal cutting driving motor is used for driving the horizontal cutting driving wheel to rotate so as to drive the horizontal cutting steel belt cutter to rotate; the traverse unit includes: the cutting device comprises at least one transverse cutting rack arranged along the transverse direction, at least two transverse cutting gears rotatably arranged below a transverse cutting fixing frame, and a transverse cutting movement driving motor used for driving the transverse cutting gears to rotate in a reciprocating manner; the transverse cutting rack is meshed with the transverse cutting gear.

Further, full-automatic multilayer gauze laminating dicing filler equipment, wherein, hold in the palm the material mechanism and still include: hold in the palm work or material rest and a plurality of area conveying subassembly, it fixes to hold in the palm the work or material rest, it is located to hold in the palm the below of material platform that a plurality of area conveying subassemblies are located hold in the palm the material platform, it has a plurality of openings on the material platform to hold in the palm, area conveying subassembly includes: the conveying belt capable of moving along the conveying direction of the material belt is capable of being output, the conveying belt leaks from the opening, and the surface of the conveying belt is superposed on the surface of the material supporting platform.

Further, full-automatic multilayer gauze laminating dicing filler equipment, wherein, the area conveying subassembly still includes: the driving device comprises two fixing plates arranged along the transverse direction, two driven transmission shafts and a main transmission shaft which are rotatably arranged between the two fixing plates, two driven wheels respectively arranged at the same ends of the two driven transmission shafts, a driving wheel arranged at the same end of a driving shaft and a driving wheel driving motor; the main transmission shaft is positioned below the two driven transmission shafts, the two driven transmission shafts are sequentially arranged along the longitudinal direction, the plane where the topmost ends of the two driven transmission shafts are located is a horizontal plane, the conveyor belt is wound on the two transmission shafts and the main transmission shaft, and the driving wheel driving motor is in transmission connection with the driving wheel and used for driving the driving wheel to rotate so as to drive the conveyor belt to rotate; the plane of the parts of the conveyor belt positioned on the two driven shafts is superposed with the surface of the material supporting platform.

Further, full-automatic multilayer gauze laminating dicing filler equipment, wherein, compress tightly the absorption transfer mechanism and include: the device comprises a cantilever frame, at least two rows of pressing plate groups, a cantilever frame lifting driving assembly, a cantilever frame longitudinal driving assembly and a negative pressure switching assembly; the at least two rows of pressing plate groups are arranged on the cantilever frame and comprise a plurality of pressing plates arranged along the transverse direction, the lower surfaces of the pressing plates face downwards, a plurality of adsorption holes are uniformly distributed on the lower surfaces of the pressing plates, and the adsorption holes are communicated with the negative pressure switching assembly; the negative pressure switching assembly is used for switching the adsorption holes among negative pressure, atmospheric pressure and broken vacuum pressure; the cantilever frame lifting driving assembly is used for driving the cantilever frame to ascend or descend, and the cantilever frame longitudinal driving assembly is used for driving the cantilever frame to reciprocate in the longitudinal direction; the negative pressure switching assembly comprises: closely laminate, but and relative movement's first regulating plate and second regulating plate, be provided with three rows on the first regulating plate and adjust the punch combination, be provided with one row of connecting hole group on the second regulating plate, three rows adjust the punch combination from the top down and set gradually include: a negative pressure regulating hole group, an atmospheric pressure regulating hole group and a vacuum breaking regulating hole group; the negative pressure adjusting hole group, the atmospheric pressure adjusting hole group, the vacuum breaking adjusting hole group and the connecting hole group comprise at least two through holes with the same interval and the corresponding positions, the negative pressure adjusting hole group is externally connected with a negative pressure device generating negative pressure, the atmospheric pressure adjusting hole group is communicated with the atmosphere, and the vacuum breaking adjusting hole group is externally connected with a blowing device generating blowing force.

Further, full-automatic multilayer gauze laminating dicing filler equipment, wherein, fixed length feeding mechanism includes: an upper pull roll, a lower pull roll, an upper pull roll drive assembly, and a pull drive assembly; the upper traction roller and the lower traction roller are arranged along the transverse direction, and the upper traction roller driving assembly is used for driving the upper traction roller to move towards or away from the lower traction roller; the traction driving assembly is used for driving the upper traction roller or the lower traction roller to intermittently rotate along the conveying direction of the material belt.

The invention has the beneficial effects that:

the application provides a full-automatic multilayer gauze covers closes dicing filler equipment includes: the feeding mechanism is used for stacking and feeding a plurality of material belts; the longitudinal cutting mechanism is used for cutting the plurality of material belts which are stacked and fed with materials along the longitudinal direction to form a plurality of material strips; the fixed-length feeding mechanism is used for outputting the plurality of material strips in a fixed length manner; hold in the palm material mechanism, it includes: the material supporting platforms are sequentially arranged along the longitudinal direction and used for supporting the plurality of material strips which are output in a fixed length mode; at least two transverse cutting channels are formed between the material supporting platform close to the fixed-length feeding mechanism and between two adjacent material supporting platforms; the pressing adsorption transfer mechanism is used for pressing the plurality of material strips on the material supporting platform; horizontal cutting mechanism, it includes: the horizontal cutting and traversing unit is used for driving the horizontal cutting and traversing units to respectively reciprocate along the at least two horizontal cutting channels, and the at least two horizontal cutting units are used for cutting the plurality of strips pressed on the material supporting platform to form a plurality of material blocks; the pressing, adsorbing and transferring mechanism is further used for adsorbing and transferring the blocks to a conveying line along the longitudinal direction. When the device is used for producing the gauze pieces, the working procedure does not need to be rotated, and the production efficiency is obviously improved.

Drawings

FIG. 1 is a schematic diagram of a fully automatic multi-layer gauze packing, dicing and packing apparatus provided herein;

FIG. 2 is a front view of the fully automatic multi-layer gauze packing, dicing and packing apparatus provided herein;

FIG. 3 is a top view of FIG. 2;

FIG. 4 is a schematic structural diagram of a feeding mechanism provided in the present application;

FIG. 5 is a schematic structural diagram of a horizontal cutting unit provided by the present application;

FIG. 6 is a schematic structural diagram of a longitudinal cutting mechanism provided in the present application;

FIG. 7 is a right side view of FIG. 6;

FIG. 8 is a top view of FIG. 6;

FIG. 9 is a front view of a cross cutting mechanism provided herein;

FIG. 10 is a left side view of FIG. 9;

FIG. 11 is a schematic structural view of a material supporting mechanism and a pressing and adsorbing mechanism provided by the present application;

FIG. 12 is a top view of FIG. 11;

fig. 13 is a schematic structural diagram of a horizontal cutting unit provided by the present application.

Detailed Description

The present application will be described in further detail below with reference to the accompanying drawings by way of specific embodiments.

The application provides a full-automatic multilayer gauze covers closes stripping and slicing filler equipment for after covering and closing out multilayer gauze, indulge the sanction to multilayer gauze, violently cut out again, in order to cut out the gauze piece, and with the gauze piece shift to the packing groove of flat packaging machine conveyer belt, pack the gauze piece through flat packaging machine.

In the following embodiments, the transverse direction is the length direction of the material belt, the longitudinal direction is the width direction of the material belt, the material belt is a multilayer gauze, and the material blocks are multilayer gauze blocks.

Referring to fig. 1 to 13, the fully automatic multi-layer gauze-covered diced filling apparatus provided in this embodiment includes: the device comprises a feeding mechanism 10, a longitudinal cutting mechanism 20, a fixed-length feeding mechanism 30, a material supporting mechanism 40, a pressing, adsorbing and transferring mechanism 50, a transverse cutting mechanism 60, a first buffer mechanism 70 and a second buffer mechanism 80 which are sequentially connected.

The feeding mechanism 10 is used for stacking a plurality of material strips 100 into a material, the longitudinal cutting mechanism 10 is used for cutting the plurality of material strips stacked into a material along the longitudinal direction to form a plurality of material strips, the fixed-length feeding mechanism 30 is used for outputting the formed plurality of material strips in a fixed length and outputting the material strips fed in a fixed length to the supporting mechanism 40, the supporting mechanism 40 is used for supporting the plurality of material strips output in a fixed length, the pressing and adsorbing transfer mechanism 50 (not found in the drawing) is used for pressing the plurality of material strips supported on the supporting mechanism 40, the transverse cutting mechanism 60 is used for cutting the plurality of material strips 101 pressed on the supporting mechanism 20 (marked by errors) along the transverse direction to form a plurality of material blocks 102, the pressing and adsorbing transfer mechanism 50 is also used for adsorbing and transferring the plurality of material blocks 102 to the conveying line 91 of the plane packaging machine 90 along the longitudinal direction, the conveying line 91 sequentially conveys the plurality of material blocks 102 to the plane packaging machine 90 for packaging, thus, the production efficiency of the gauze piece is improved.

The feeding mechanism 10 feeds a plurality of gauze rolls in a stacked manner, as shown in fig. 2 and 4, the feeding mechanism 10 includes: a plurality of units 11 that unreel to and pan feeding traction unit 12, each unreels unit 11 and all includes: unreel axle 111 and unreel axle power roller 112, wherein, unreel axle 111 and unreel axle power roller 112 mutual parallel arrangement, unreel axle 111 is used for unreeling the rotation of spool axial lead to unreel the discharging strip, can regard as the width of unreeling the gauze material area that axle 111 unreeled in every unreeling unit 11 unanimously or not unanimously. The unreeling shaft power roller 112 is used for pressing the material belt wound on the unreeling shaft 111 and rotating around the unreeling shaft power roller axis line so as to drive the unreeling shaft 111 to rotate. That is, the rotating unwinding shaft power roller 112 drives the unwinding shaft 111 to rotate by a friction force generated with the surface of the wound tape, and provides power for the rotation of the unwinding shaft 111. The feeding pulling unit 12 includes: the axial direction of the feeding traction rollers 121 is the transverse direction, and the feeding traction rollers 121 are driven to rotate by a feeding traction driving motor, so that the feeding traction rollers 121 output rotary motion along the longitudinal positive direction, and a plurality of material belts 100 output in a stacked mode are pulled to the fixed-length feeding mechanism 30.

In this application, the rotational linear velocity of pan feeding carry over pinch rolls 121 is greater than the rotational linear velocity of unreeling axle power roller 111 to provide tension for the multilayer gauze of pan feeding, avoid appearing phenomenons such as wrinkling, dislocation, off tracking.

In this embodiment, the unwinding shafts 111 and the unwinding shaft power rollers 112 in the unwinding units 11 are parallel to each other, so that the center lines of the tapes unwound by the unwinding shafts 111 in the unwinding units 11 are in the same plane, that is, the tapes unwound by the unwinding shafts 111 are stacked.

In some embodiments, the unwinding units 11 are sequentially arranged in an up-down direction, so that the unwinding tapes from the unwinding shafts 111 can be stacked conveniently. In other embodiments, the unreeling units 11 are arranged in a staggered manner in the vertical direction and the front-back direction, in other words, the unreeling units 11 are divided into two upper rows and two lower rows, the axial lines of the unreeling shafts 111 in a part of the unreeling units 11 in the upper row may or may not be in the same plane, and the axial lines of the unreeling shafts 111 in another part of the unreeling units 11 in the lower row may or may not be in the same plane, so that the installation space of the device can be saved.

In this embodiment, the plurality of unwinding units 11 are arranged in a staggered manner in the up-down direction and the front-back direction, that is, the plurality of unwinding units 11 are divided into two upper rows and two lower rows, the axial lines of the unwinding shafts 111 in a part of the unwinding units 11 in the upper row are in the same plane, the axial lines of the unwinding shafts 111 in another part of the unwinding units 11 in the lower row are in the other plane, and the two planes are parallel to each other. Thus, a rolling unit 13 is further disposed between the two rows of unwinding units 11, and the rolling unit 13 includes: the device comprises at least one first rolling component and a second rolling component, wherein the first rolling component and the second rolling component are arranged between an upper row of unreeling units 11 and a lower row of unreeling units 11. The first rolling assembly is used for rolling at least two material belts which are wound by the unwinding shafts 111 and staggered in the vertical direction, and the second rolling assembly is used for rolling at least two material belts which are rolled by the first rolling assembly and the material belts which are wound by the unwinding shafts 111 to form the multi-layer material belt.

Taking fig. 2 and 4 as an example, five unwinding units 11 are provided, and the formed material belt is five material belts, wherein two unwinding units are arranged on the upper row, three unwinding units are arranged on the lower row, two first rolling assemblies are arranged, and one second rolling assembly is arranged. Taking the front-back direction shown in fig. 2 as an example, the first front rolling component is used for rolling the material strips discharged by the first upper discharging reel and the first lower discharging reel to form two layers of material strips, the second rear rolling component is used for rolling the formed two layers of material strips, the material strips discharged by the second upper discharging reel and the material strips discharged by the second lower discharging reel to form four layers of material strips, and the second rolling component is used for rolling the four layers of material strips and the material strips discharged by the third lower discharging reel to form five layers of material strips.

It will be appreciated that the first and second roller assemblies each comprise: an upper roller 131 and a lower roller 132 are provided one above the other, and the upper roller 131 and the lower roller 132 are parallel to each other and to the unreeling shaft 111 and the unreeling shaft power roller 112.

In the above embodiment, the rotation directions of the unwinding shaft power rollers 112 in the two unwinding units 11 at the upper row and the respective unwinding shaft power rollers 112 in the three unwinding units at the lower row are opposite (for example, the two unwinding shaft power rollers 112 at the upper row rotate in the clockwise direction, and the three unwinding shaft power rollers 112 at the lower row rotate in the counterclockwise direction), so as to drive the respective corresponding unwinding shafts 111 to rotate in the rotation directions opposite to the rotation directions of the unwinding shaft power rollers 112 (for example, the two unwinding shafts 111 corresponding to the two unwinding shaft power rollers 112 at the upper row rotate in the counterclockwise direction, and the three unwinding shafts 111 corresponding to the three unwinding shaft power rollers 112 at the lower row rotate in the clockwise direction), so as to output a single layer of gauze in the same direction.

In order to ensure that the unreeling shaft power roller 112 always presses the wound material strip on the unreeling shaft 111, the unreeling shaft power roller 112 can move towards the direction of the unreeling shaft 111 along with the reduction of the roll diameter of the material strip wound on the unreeling shaft 111. Specifically, the unwinding unit 11 further includes: the vertical plate 113 and the pressing driving component, the same end of the unwinding shaft 111 in each unwinding unit 11 is rotatably mounted on the front surface of the vertical plate 113. The compression drive assembly includes: a drive motor (not shown), a mounting shaft 114, a mounting cylinder 115, two swing arms 116, and at least one swing arm drive cylinder 117. The mounting cylinder 115 is fixed on the vertical plate 113, the mounting shaft 114 penetrates through the mounting cylinder 115 and is rotatably mounted on the vertical plate 113, one end of the mounting shaft 114 penetrates through the vertical plate 113 and then is located on the back of the vertical plate 113, and the other end of the mounting shaft 114 leaks out of the mounting cylinder 115. The driving motor is installed on the back of the vertical plate 113. Two swing arms 116 are fixed on the mounting cylinder 115 in parallel, and the unreeling shaft power roller 112 is rotatably mounted between the two swing arms 116. The driving motor and one end of the mounting shaft 114 penetrating through the vertical plate 113 are in transmission connection through a chain transmission mechanism or a belt transmission mechanism, and the other end of the mounting shaft 114 leaking out of the mounting cylinder 115 is in transmission connection with the unreeling shaft power roller 112 through a chain transmission mechanism or a belt transmission mechanism. The fixed end of swing arm driving cylinder 117 is hinged on vertical plate 113, and the piston rod end is hinged on one swing arm 116. The swing arm driving cylinder 117 is used for driving the swing arm 116 to move towards the direction close to the unreeling shaft 111 so as to enable the unreeling shaft power roller 112 to press the coiled material wound on the unreeling shaft 111, or the swing arm driving cylinder 117 is used for driving the swing arm 116 to move towards the direction far away from the unreeling shaft 111 so as to enable a material passing space to be formed between the unreeling shaft 111 and the unreeling shaft power roller 112 so as to pass the tape. The driving motor is used for driving the mounting shaft 111 to rotate, so that the unwinding shaft power roller 112 is driven to rotate after the unwinding shaft power roller 112 compresses the material belt wound on the unwinding shaft 111, and the unwinding shaft 111 is provided with rotating power, so that the material belt is released.

In the above embodiment, one end of the unwinding shaft 111 is rotatably mounted on the vertical plate 113, and the unwinding shaft 111 has a sufficient diameter to bear a corresponding weight of the wound material tape, so that the unwinding shaft 111 is not crushed by an excessively heavy wound material tape.

In this embodiment, the unwinding shaft 111 is an air expansion shaft, the wound material tape is wound on a paper tube, the paper tube is threaded on the air expansion shaft, and an inflation port of the air expansion shaft is inflated to fix the wound material tape. In general, the position of the wound tape on each unwinding shaft 111 is not fixed, and there is a certain deviation inevitably, and then the unwinding unit 11 further includes: the unreeling shaft deviation rectifying assembly is arranged at one end of the unreeling shaft 111 and used for enabling the unreeling shaft 111 to move in a reciprocating mode along the axis line direction of the unreeling shaft 111 so as to adjust the material belts to be at the same position. The deviation rectifying component of the unreeling shaft is of an existing design, and the structure of the deviation rectifying component is not described in detail.

The longitudinal cutting mechanism 20 is used for cutting the plurality of material strips stacked with the material to form a plurality of material strips along the longitudinal direction. Should indulge cutting mechanism includes: the device comprises a plurality of longitudinal cutting units 21 and a longitudinal cutting traction unit 22, wherein the longitudinal cutting units 21 are used for cutting the plurality of material belts which are fed in a laminated mode to form a plurality of material strips, and the longitudinal cutting traction unit 22 is used for drawing and feeding the plurality of material strips to a fixed-length feeding mechanism 30. The plurality of longitudinal cutting units 21 are arranged in a staggered manner.

Referring to fig. 6 to 8, the slitting unit 21 includes: a longitudinal cutting fixing frame 211, a longitudinal cutting driving wheel 212, at least one longitudinal cutting driven wheel 213, a longitudinal cutting steel band knife 214, a longitudinal cutting driving motor 215 and at least one longitudinal cutting grinding wheel 216. The longitudinal cutting driving wheel 212, the at least one longitudinal cutting driven wheel 213, the longitudinal cutting steel band knife 214, the longitudinal cutting driving motor 215 and the at least one longitudinal cutting grinding wheel 216 are all installed on the longitudinal cutting fixing frame 211, the width direction of the longitudinal cutting steel band knife 214, the axial direction of the longitudinal cutting driving wheel 212 and the axial direction of the longitudinal cutting driven wheel 213 are longitudinal directions, the centers of the longitudinal cutting driving wheel 212 and the longitudinal cutting driven wheel 213 are in the same plane, the plane is perpendicular to the plurality of stacked material bands 100, the longitudinal cutting steel band knife 214 is wound on the longitudinal cutting driving wheel 212 and the longitudinal cutting driven wheel 213, the longitudinal cutting steel band knife 214 is provided with a cutting edge facing the conveying direction of the material bands, and the longitudinal cutting driving motor 215 is used for driving the longitudinal cutting driving wheel 212 to rotate so as to drive the longitudinal cutting driven wheel 213 to rotate, and accordingly drive the longitudinal cutting steel band knife 214 to rotate. The plurality of material tapes 100 stacked in layers are conveyed in the longitudinal direction and cut by the longitudinal-cutting steel tape cutters 214 rotating on the longitudinal-cutting units 21 to form a plurality of material strips.

The rip fence pulling unit 22 includes: and a pair of longitudinal drawing rollers 221, wherein the pair of longitudinal drawing rollers 221 are driven to rotate by a main cutting drawing driving motor so as to output the formed plurality of strips to the long feeding mechanism 30.

The definite length feeding mechanism 30 is used for outputting the plurality of formed material strips to the supporting mechanism 40 in definite length.

As shown in fig. 9, the definite length feeding mechanism 30 includes: an upper pull roll 31, a lower pull roll 32, an upper pull roll drive assembly 33, and a pull drive assembly (not shown). The upper traction roller 31 and the lower traction roller 32 are arranged along the transverse direction, the upper traction roller driving assembly 33 is used for driving the upper traction roller 31 to move towards the direction of the lower traction roller 32 so as to press the material belt, and the upper traction roller driving assembly 33 is also used for driving the upper traction roller 31 to move away from the direction of the lower traction roller 32 so as to form a material passing space between the upper traction roller 31 and the lower traction roller 32. The traction drive assembly is used for driving the upper traction roller 31 or the lower traction roller 32 to rotate intermittently along the conveying direction of the material belt. The plurality of material strips 100 are threaded between the upper pulling roll 31 and the lower pulling roll 32 through the material passing space, and the upper pulling roll driving assembly 33 drives the upper pulling roll 31 to move towards the lower pulling roll 32, so that the upper pulling roll 31 presses the lower pulling roll 32, and the plurality of material strips 100 are basically restrained in the same plane. Then, the pull roll driving assembly drives the upper pull roll 31 or the lower pull roll to intermittently rotate along the conveying direction of the material strip, so that the plurality of material strips 100 are sequentially output with fixed length.

Specifically, after the upper pulling roll driving assembly 33 drives the upper pulling roll 31 to move towards the lower pulling roll, the pulling roll driving assembly drives the upper pulling roll 31 or the lower pulling roll 32 to intermittently rotate along the conveying direction of the material belt so as to feed materials with fixed length. The traction driving component can be a servo motor controlled by a controller, and the controller outputs a pulse signal to control the servo motor to intermittently rotate so as to achieve the purpose of fixed-length feeding.

The material supporting mechanism 40 is arranged at the output end of the fixed-length feeding mechanism 30, and the material supporting mechanism 40 comprises: the material supporting platforms 41 are used for supporting the material belt which is output in a fixed length mode by the fixed-length feeding mechanism 30. The at least two material supporting platforms 41 are sequentially arranged along the longitudinal direction, in other words, the length direction of the at least two material supporting platforms 41 is the transverse direction, and the at least two material supporting platforms 41 are parallel to each other, that is, the surfaces of the at least two material supporting platforms 41 are in the same plane, and the same plane is preferably a horizontal plane.

In the present application, a certain gap is formed between the material supporting platform 41 close to the fixed-length feeding mechanism 30 and the fixed-length feeding mechanism 30, and between two adjacent material supporting platforms 41, so that at least two transverse cutting channels 42 (as shown in fig. 1) are formed between the material supporting platform 41 close to the fixed-length feeding mechanism 30 and the fixed-length feeding mechanism 30, and between two adjacent material supporting platforms 41.

The cross cutting mechanism 60 includes: the transverse cutting device comprises at least two transverse cutting units 61 and a transverse cutting transverse moving unit 62, wherein the at least two transverse cutting units 61 correspond to the at least two transverse cutting channels 42 respectively, and the transverse cutting transverse moving unit 62 is used for driving the at least two transverse cutting units 61 to reciprocate along the at least two transverse cutting channels 42 respectively, namely, when the transverse cutting transverse moving unit 62 drives the at least two transverse cutting units 61 to reciprocate along the at least two transverse cutting channels 42 respectively, the transverse cutting units 61 move from one side to the other side of the material belt along the transverse direction of the material belt. At least two transverse cutting units 61 are used for cutting the material belt pressed on the material supporting platform 41. The pressing, adsorbing and transferring mechanism 50 is further configured to adsorb the cut material tape and transfer the material tape to the conveying line 91 of the flat packing machine 90 along the longitudinal direction.

As shown in fig. 13, the horizontal cutting unit 61 includes: a sidewinder 611 (shown in fig. 10), a sidewinder 612, at least one sidewinder 613, a sidewinder motor 614, a sidewinder drive motor 615, and at least one sidewinder wheel 616. A cutting drive wheel 612, at least one cutting driven wheel 613, a cutting steel belt knife 614, a cutting drive motor 615, and at least one cutting grinding wheel 616 are mounted on the cutting holder 611, and the width direction of the cutting steel belt knife 614, the axial direction of the cutting drive wheel 612, and the axial direction of the cutting driven wheel 613 are all transverse directions. The centers of the driving and driven slitting wheels 612, 613 are in the same plane, which is perpendicular to the web. A steel band slitting knife 614 is wound around a driving slitting wheel 612 and at least one driven slitting wheel 613, the steel band slitting knife 614 having a cutting edge directed in the transverse direction of the web. The cutting drive motor 615 is used for driving the cutting drive wheel 612 to rotate, thereby driving the cutting steel band knife 614 to rotate. At least one sidecut grinding wheel 616 is used to grind the edge of the sidecut steel band knife 614 so that the edge of the sidecut steel band knife 614 is always sharp, extending the useful life of the sidecut steel band knife 614.

As shown in fig. 10, the traverse unit 62 includes: at least one cross cutting rack 621, at least two cross cutting gears 622, and a cross cutting movement driving motor 623. The length direction of at least one cutting rack 621 is arranged along the transverse direction, and at least two cutting gears 622 are rotatably mounted below the cutting holder 611, wherein the cutting racks 621 are meshed with the cutting gears 622, and the cutting driving motor 423 is used for driving the cutting gears 622 to rotate in a reciprocating manner, so that the cutting holder 611 is driven to move in a reciprocating manner along the length direction of the cutting racks 621, namely, at least two cutting units 61 are driven to move in a reciprocating manner in the transverse direction.

In this application, the material supporting platforms 41 are provided with at least two, and the plurality of material strips are output to the aforementioned at least two material supporting platforms 41 under the traction feeding of the fixed-length feeding mechanism 30, that is, the plurality of material strips output at fixed length are sequentially conveyed from one material supporting platform 41 to the next material supporting platform 41. For the conveying efficiency who improves the material strip, this holds in the palm material mechanism 40 still includes: a material support frame 43 and a plurality of belt conveying assemblies, wherein the material support platform 41 is fixed on the material support frame 43, and the plurality of belt conveying assemblies are fixed below the material support platform 41, wherein the belt conveying assemblies comprise: the conveying belt is used for outputting the conveying belt moving along the conveying direction of the material belt, a plurality of openings are formed in the material supporting platform 41, the openings correspond to the belt conveying assemblies one by one respectively, the conveying belt leaks from the openings, and the surface of the conveying belt leaking from the openings is overlapped on the plane where the surface of the material supporting platform is located. So, can carry out the secondary conveying to a plurality of material strips of fixed length output along the conveyer belt of material area direction of transfer conveying, avoid the material strip of fixed length output to appear the phenomenon of staggered floor, corrugate to improve production quality.

As above, each belt conveying assembly further includes: two fixed plates 44, two driven shafts, a main drive shaft 45, two driven wheels 46, a drive wheel 47, and a drive wheel drive motor 48. Two fixed plates 44 are arranged in sequence along the transverse direction and fixed below the material supporting platform 41, two driven transmission shafts and a main transmission shaft 45 are rotatably arranged between the two fixed plates 44, the main transmission shaft 45 is positioned below the two driven transmission shafts, two driven wheels 46 are respectively arranged on the two driven transmission shafts, a driving wheel 47 is arranged at the end part of the driving shaft 25, and the conveyor belt is wound on the two transmission shafts and the main transmission shaft 45. The two fixing plates 44 are positioned so as to allow the conveyor belt to escape through the openings provided in the material holding platform 41. The two driven transmission shafts are sequentially arranged along the longitudinal direction, the plane where the topmost end of the two driven transmission shafts is located is a horizontal plane, and a driving wheel driving motor 48 is in transmission connection with a driving wheel 47 and is used for driving the driving wheel to rotate so as to drive the conveyor belt to rotate along the material belt conveying direction. The conveyor belt is positioned on two parts on the transmission shaft, namely, the part which leaks out of the opening of the material supporting platform 41, and the plane of the part is superposed with the plane of the surface of the material supporting platform 41.

In the above embodiment, the main drive shafts 45 in the plurality of belt conveying assemblies are coaxial, i.e., share one main drive shaft 45, one drive wheel 47 and one drive wheel drive motor 48 for transmission.

In this application, since the material belt is a plurality of material strips 100 constrained in the same plane, the pressing adsorption transfer mechanism 50 includes: a cantilever frame 51, at least two rows of pressing plate groups, a cantilever frame lifting driving assembly 52, a cantilever frame longitudinal driving assembly 53 and a negative pressure switching assembly 55. At least two rows of pressure plate groups are installed on cantilever frame 51, wherein, every row of pressure plate group all includes a plurality of clamp plates 56 along the transverse direction range, and each clamp plate 56 all has lower surface down, and this lower surface orientation material piece that forms, and the lower surface of clamp plate 56 all equipartition has a plurality of absorption holes, and this a plurality of absorption holes and negative pressure switching component 55 intercommunication, negative pressure switching component 55 are used for making this a plurality of absorption holes switch between negative pressure, atmospheric pressure and broken vacuum pressure. The boom housing elevation driving assembly 52 is configured to drive the boom housing 51 to ascend or descend, and the boom housing longitudinal driving assembly 53 is configured to drive the boom housing 51 to reciprocate in the longitudinal direction.

Specifically, before the transverse cutting unit 61 cuts, the cantilever frame lifting driving assembly 52 drives the cantilever frame 51 to descend, so that the pressing plate 56 presses the plurality of strips output at fixed length on the material supporting platform 41, and then the transverse cutting unit 61 moves along the transverse cutting channel 42 under the driving of the transverse cutting and transverse moving unit 62, so that the plurality of strips output at fixed length are cut into a plurality of material blocks. While cutting, the negative pressure switching assembly 34 makes the adsorption hole in a negative pressure state to adsorb the block. Then, the cantilever frame elevation driving assembly 52 drives the cantilever frame 51 to ascend to drive the pressing plate 56 to ascend, and the cantilever frame longitudinal driving assembly 53 drives the lifted cantilever frame 51 to move along the conveying direction of the plurality of material strips in the longitudinal direction, so that the material blocks adsorbed by the pressing plate 56 move above the conveying line 91 of the flat packing machine 90. Then, the negative pressure switching assembly 55 switches the suction hole to be in the atmospheric pressure state and then in the vacuum breaking state, thereby releasing the material block.

The negative pressure switching assembly 55 includes: first regulating plate 551 and second regulating plate 552, first regulating plate 551 and second regulating plate 552 closely laminate, but and relative movement, are provided with three rows of regulation punch combination on first regulating plate 551, are provided with one row of connection punch combination on the second regulating plate 552, and three rows of regulation punch combination are including setting gradually: the negative pressure adjusting hole group, the atmospheric pressure adjusting hole group and the vacuum breaking adjusting hole group, the negative pressure adjusting hole group, the atmospheric pressure adjusting hole group, the vacuum breaking adjusting hole group and the connecting hole group all comprise at least two through holes with the same distance and corresponding positions, the connecting hole group is used for being communicated with the adsorption holes on the pressing plate 56, the negative pressure adjusting hole group is externally connected with a negative pressure device for generating negative pressure, the atmospheric pressure adjusting hole group is communicated with the atmosphere, and the vacuum breaking adjusting hole group is externally connected with a blowing device for generating blowing force. When the first adjustment plate 551 and the second adjustment plate 552 are relatively moved to the negative pressure adjustment hole set to be butted against the connection hole set, the suction holes of the pressure plate 56 generate a negative pressure to suck the lump. When the first adjustment plate 551 and the second adjustment plate 552 are relatively moved to the atmospheric pressure adjustment hole set and the connection hole set, the suction holes of the pressure plate 56 are communicated with the atmospheric pressure. When the first adjusting plate 551 and the second adjusting plate 552 are relatively moved to the vacuum breaking adjusting hole set and the connecting hole set, the suction holes of the pressing plate 56 generate a blowing force to blow off the lump, and the lump is released to the conveying line 91.

Further, the negative pressure switching assembly 55 further includes: the switching driving unit 553 is arranged on the top of the negative pressure switching gantry 554, and is used for outputting up-and-down reciprocating motion to drive the first adjusting plate 551 to move relative to the second adjusting plate 552, or drive the second adjusting plate 552 to move relative to the first adjusting plate 551. The switching driving unit 553 includes two cylinders, a rod end of one cylinder is connected to the adjusting plate, a rod end of the other cylinder is fixed to the negative pressure switching gantry 554, the two cylinders are both disposed in a vertical direction, and the two cylinders are fixed to each other. Through the stretching of the two cylinders, the relative movement of the two adjusting plates is realized, and the switching of the adsorption holes on the pressing plate 56 among vacuum pressure, atmospheric pressure and broken vacuum pressure is further realized.

In this application, be provided with two row at least filler groove groups along its length direction on the transfer chain 91, every row of filler groove group all includes a plurality of equidistant filler groove 911 that set up, what each filler groove 911 corresponds still is provided with filler groove push pedal 912, and the interval between the adjacent filler groove 911 is greater than the interval between the adjacent clamp plate 56. The aforesaid clamp plate group still includes: and a plurality of communication shells 57, wherein the plurality of communication shells 57 correspond to the plurality of pressure plates 56 one by one, and the communication shells 57 are communicated with each other through telescopic pipes. The cantilever frame 51 is further provided with a plurality of slide rails, the communicating shells 57 on the pressure plates 56 at the same end in each row of pressure plate groups are fixed on the cantilever frame 37, and the communicating shells 57 on the other pressure plates 56 are slidably arranged on the slide rails through slide blocks. And a communicating shell transverse driving cylinder 58 is further arranged between every two adjacent communicating shells 57, and the communicating shell transverse driving cylinder 58 is used for driving the distance between every two adjacent pressing plates 56 to be equal to the distance between every two adjacent stuffing grooves 911 when the pressing plates 56 move to the position above the conveying line.

The gauze piece that this application formed is the gauze piece that has twenty-five layers of gauze, as shown in fig. 2 and fig. 4, this application is provided with five and unreels unit 11, and then what every unreel unit 11 unreeled is five layers of gauze rolls. Under the general condition, the volume is cut to gauze is the individual layer gauze, then this application should also cover earlier out five layers of gauze before covering twenty-five layers of gauze and cut the volume, then in this application, still include the rolling unit 14 that rolls up and carry out the rolling to five layers of gauze, as shown in fig. 2, fig. 4 and fig. 5, this receiving unit 14 includes: the winding device comprises a winding shaft 141 and a winding shaft power roller 142, wherein the winding shaft 141 and the winding shaft power roller 142 are parallel to each other, and the winding shaft 141 is used for rotating around the axial lead of the winding shaft so as to wind and receive the multilayer material belt. The winding shaft power roller 142 is used for clinging to the coil on the winding shaft 141 and rotating around the axial lead of the winding shaft power roller so as to drive the winding shaft 141 to rotate. That is, the rotating winding shaft power roller 142 drives the winding shaft 141 to rotate by the friction force with the material wound on the winding shaft 141, so as to provide power for the rotation of the winding shaft 141.

In a preferred embodiment, the takeup reel 141, the takeup reel power roller 142, the takeup reel 111, and the takeup reel power roller 112 are all parallel to one another.

In this embodiment, the linear velocity of the unwinding shaft power roller 112 is less than the linear velocity of the winding shaft power roller 142, so that tension can be provided for the multilayer gauze when the winding shaft 141 is wound, and the phenomena of wrinkling, dislocation, deviation and the like of the multilayer gauze are avoided.

In order to ensure that the winding shaft 141 always compresses the winding shaft power roller 142, the winding shaft 141 can move in a direction away from the winding shaft power roller 142 along with the increase of the diameter of the multi-layer material belt wound on the unwinding shaft 31. Specifically, as shown in fig. 5, the material receiving unit 14 further includes: the winding shaft 141 is positioned above the winding shaft power roller 142, the winding shaft power roller 142 is rotatably arranged on the portal frame 143, the sliding component can output reciprocating motion along the vertical direction, the sliding component comprises sliding rails arranged on two side edges of the portal frame 143 and sliding blocks arranged on the sliding rails in a sliding mode, and the winding shaft 141 is rotatably arranged between the two sliding blocks. When the diameter of the multilayer gauze roll wound on the winding shaft 141 is increased, the winding shaft 141 moves upwards along the slide rail under the guiding action of the slide rail so as to depart from the power roller 142 of the winding shaft.

In the above embodiment, the winding shaft power roller 142 and the unwinding shaft power roller 112 may share one driving motor for driving, and similarly, the driving motor and the winding shaft power roller 112 are driven by a chain transmission mechanism or a belt transmission mechanism. Meanwhile, in order to ensure that the two power rollers have different linear speeds, the two power rollers adopt chain wheel sets or belt wheel sets with different transmission ratios for transmission.

For the effect of lapping when improving the rolling, this winding mechanism still includes: and the force applying assembly is positioned above the winding shaft 141 and is used for providing force for the winding shaft 141 to press the winding shaft power roller 142. Specifically, this application of force subassembly includes: a driving cylinder 144 fixed on the top end of the portal frame 143, and a clamping groove 145 fixed on the piston rod end of the driving cylinder 144. Two mounting positions of the portal frame 143, which are used for mounting two ends of the winding shaft 141, are respectively provided with a lower groove, a bearing is mounted in the lower groove, two ends of the winding shaft 141 are arranged in the bearing in a penetrating manner, and the clamping groove 145 is fixedly clamped with the lower groove so as to clamp the bearing between the clamping groove 145 and the lower groove. Therefore, when the diameter of the multi-layer gauze roll on the winding shaft 141 is increased, the driving cylinder 144 retracts, downward pressure can be provided for the winding shaft 141, and the winding and rolling effect is guaranteed.

In some embodiments, a rotating shaft 146 for fixing through two bearings 147 is further disposed at the top end of the gantry 143, two ends of the two rotating shafts 146 are connected with two ends of the winding shaft 32 through a chain transmission mechanism, and when the winding shaft 141 moves up and down, the rotating winding shaft 141 drives the rotating shaft 146 to rotate through the chain transmission mechanism 149, so that parallelism of the winding shaft 141 relative to the winding shaft power roller 142 can be ensured, and thus, a winding and coiling effect is further ensured.

In this application, the operating frequency of pan feeding traction drive motor in pan feeding traction unit 12 is far below the operating frequency of the longitudinal cutting traction drive motor in longitudinal cutting traction unit 22, and for protecting pan feeding traction drive motor, then still be provided with first buffer memory mechanism 70 between pan feeding mechanism 10 and longitudinal cutting mechanism 20 to buffer the material strip of transmission, this first buffer memory mechanism 70 includes: the axial direction of the first material passing rollers 71 is the transverse direction, and the first material passing rollers 71 are parallel to each other and arranged in a staggered mode.

Because the fixed-length feeding mechanism 30 is in an intermittent feeding mode, a second buffer mechanism 80 is further disposed between the longitudinal cutting mechanism 20 and the fixed-length feeding mechanism 30, and the second buffer mechanism 80 includes: the axial direction is the second of horizontal direction and crosses material roller 81, because the gauze that produces is twenty-five layers of gauzes, in order to prevent that pivoted second crosses material roller 81 from driving among the twenty-five layers gauze that is close to second and crosses material roller 81 and corrugate, then need keep second and cross material roller 81 and do not rotate, only need second to cross material roller 80 along the reciprocal swing of direction from top to bottom can.

The application provides a full-automatic multilayer gauze covers closes dicing filler equipment's working process as follows:

the feeding mechanism 10 stacks a plurality of material strips, the longitudinal cutting mechanism 20 cuts the plurality of material strips stacked with the material strips in the longitudinal direction to form a plurality of material strips, the plurality of material strips are conveyed to at least two material supporting platforms 41 of the material supporting mechanism 40 in a fixed length under the traction action of the fixed-length feeding mechanism 30, and the cantilever frame lifting driving component 52 drives the cantilever frame 51 to descend, so that the pressing plate 56 presses the material strips supported on the material supporting platforms 41. The traverse unit 62 drives at least two traverse units 61 along the traverse path 42, and during the movement, the rotating traverse steel band knife 614 cuts the compacted plurality of material strips to form a plurality of material blocks. During the cutting process, the negative pressure hole on the pressure plate 56 generates negative pressure through the switching of the negative pressure switching assembly 55, so as to adsorb the compacted material strips and the material blocks formed after cutting. The cantilever frame longitudinal driving assembly 53 drives the cantilever frame 51 to move above the conveying line 91 along the longitudinal direction, the communicating shell transverse driving cylinder 58 drives the distance between two adjacent pressing plates 56 to be equal to the distance between two adjacent filling grooves 911, and the negative pressure switching assembly 55 is switched to the atmospheric pressure and the vacuum breaking pressure, so that a material block is released into the filling grooves, filling is completed, and then the next cycle is started. The material blocks are intermittently pushed by a push plate 912 of a filling groove and are pushed into a plane packaging machine for packaging. The work cycle of the full-automatic multilayer gauze laminating, cutting and filling equipment is faster than the packaging speed of the plane packaging machine, so that the continuous and filling-missing-free packaging process of the plane packaging machine is ensured.

In conclusion, the full-automatic multilayer gauze laminating, cutting and filling equipment provided by the embodiment has the advantages that when gauze blocks are produced, all processes are mutually connected, the processes do not need to be rotated, and the production efficiency is obviously improved.

The foregoing is a more detailed description of the present application in connection with specific embodiments thereof, and it is not intended that the present application be limited to the specific embodiments thereof. It will be apparent to those skilled in the art from this disclosure that many more simple derivations or substitutions can be made without departing from the inventive concepts herein.

Claims (10)

1. The utility model provides a full-automatic multilayer gauze covers closes dicing filler equipment which characterized in that includes:

the feeding mechanism is used for stacking and feeding a plurality of material belts;

the longitudinal cutting mechanism is used for cutting the plurality of material belts which are stacked and fed with materials along the longitudinal direction to form a plurality of material strips;

the fixed-length feeding mechanism is used for outputting the plurality of material strips in a fixed length manner;

hold in the palm material mechanism, it includes: the material supporting platforms are sequentially arranged along the longitudinal direction and used for supporting the plurality of material strips which are output in a fixed length mode; at least two transverse cutting channels are formed between the material supporting platform close to the fixed-length feeding mechanism and between two adjacent material supporting platforms;

the pressing adsorption transfer mechanism is used for pressing the plurality of material strips on the material supporting platform;

horizontal cutting mechanism, it includes: the horizontal cutting and traversing unit is used for driving the horizontal cutting and traversing units to respectively reciprocate along the at least two horizontal cutting channels, and the at least two horizontal cutting units are used for cutting the plurality of strips pressed on the material supporting platform to form a plurality of material blocks; the pressing, adsorbing and transferring mechanism is further used for adsorbing and transferring the blocks to a conveying line along the longitudinal direction.

2. The fully automatic multi-layer gauze packing, dicing and packing apparatus of claim 1, further comprising: the setting is in pan feeding mechanism with indulge first buffer memory mechanism between the cutting mechanism, first buffer memory mechanism includes: the material roller is crossed to a plurality of first, the axial direction of first material roller of crossing is the transverse direction, a plurality of first material rollers of crossing are parallel to each other, and the dislocation is arranged.

3. The fully automatic multi-layer gauze packing, dicing and packing apparatus of claim 2 wherein the feeding mechanism comprises: a plurality of units that unreel to and pan feeding traction unit, each unreel the unit and all include: the unwinding shaft and the unwinding shaft power roller are parallel to each other, and the unwinding shaft is used for rotating around the axial lead of the unwinding shaft so as to unwind and discharge the material belt; the unwinding shaft power roller is used for pressing the coiled material raw material wound on the unwinding shaft and rotating around the axis of the unwinding shaft power roller so as to drive the unwinding shaft to rotate; the pan feeding traction unit includes: the axial direction of the feeding traction rollers is the transverse direction, and the feeding traction rollers are used for outputting movement along the longitudinal positive direction so as to draw the multiple material belts output in a laminated manner; the rotational linear speed of the feeding traction roller is greater than that of the unreeling shaft power roller.

4. The fully automatic multi-layer gauze draping, dicing, and padding apparatus of claim 1, wherein the slitting mechanism comprises: a plurality of longitudinal cutting units and a longitudinal cutting traction unit; the longitudinal cutting unit is used for cutting the plurality of material belts which are stacked and fed to form a plurality of material strips, and the longitudinal cutting traction unit is used for drawing and feeding the plurality of material strips to the fixed-length feeding mechanism; the slitting unit includes: the longitudinal cutting device comprises a longitudinal cutting driving wheel, at least one longitudinal cutting driven wheel, a longitudinal cutting steel belt cutter and a longitudinal cutting driving motor, wherein the width direction of the longitudinal cutting steel belt cutter, the axial direction of the longitudinal cutting driving wheel and the axial direction of the longitudinal cutting driven wheel are both longitudinal directions, the centers of the longitudinal cutting driving wheel and the longitudinal cutting driven wheel are in the same plane, the plane is perpendicular to the plurality of stacked material belts, the longitudinal cutting steel belt cutter is wound on the longitudinal cutting driving wheel and the longitudinal cutting driven wheel, the longitudinal cutting steel belt cutter is provided with a cutting edge facing the material belt conveying direction, and the longitudinal cutting driving motor is used for driving the longitudinal cutting driving wheel to rotate so as to drive the longitudinal cutting driven wheel to rotate; the rip cutting traction unit includes: a pair of longitudinal cutting drawing rollers.

5. The fully automatic multi-layer gauze packing and dicing filler apparatus of claim 4, further comprising: the setting is in indulge and cut out the draw unit with second buffer memory mechanism between the fixed length pan feeding mechanism, second buffer memory mechanism includes: the axial direction is the second of horizontal direction and passes the material roller, the second is passed the material roller and can be followed the up-and-down swing, but can not rotate.

6. The fully automatic multi-layer gauze packing and dicing filler apparatus of claim 1, wherein the cross-cutting unit comprises: the horizontal cutting device comprises a horizontal cutting fixing frame, a horizontal cutting driving wheel, at least one horizontal cutting driven wheel, a horizontal cutting steel band knife and a horizontal cutting driving motor, wherein the horizontal cutting driving wheel is arranged on the horizontal cutting fixing frame; the width direction of the transverse cutting steel band knife, the axial direction of the transverse cutting driving wheel and the axial direction of the transverse cutting driven wheel are all transverse directions; the centers of the transverse cutting driving wheel and the transverse cutting driven wheel are in the same plane, and the plane is vertical to the material belt; the transverse steel belt cutter is wound on the transverse driving wheel and the at least one transverse driven wheel and is provided with a blade facing the transverse direction of the material belt; the horizontal cutting driving motor is used for driving the horizontal cutting driving wheel to rotate so as to drive the horizontal cutting steel belt cutter to rotate; the traverse unit includes: the cutting device comprises at least one transverse cutting rack arranged along the transverse direction, at least two transverse cutting gears rotatably arranged below a transverse cutting fixing frame, and a transverse cutting movement driving motor used for driving the transverse cutting gears to rotate in a reciprocating manner; the transverse cutting rack is meshed with the transverse cutting gear.

7. The fully automatic multi-layer gauze packing, dicing and packing apparatus of claim 1 wherein the material holding mechanism further comprises: hold in the palm work or material rest and a plurality of area conveying subassembly, it fixes to hold in the palm the work or material rest, it is located to hold in the palm the below of material platform that a plurality of area conveying subassemblies are located hold in the palm the material platform, it has a plurality of openings on the material platform to hold in the palm, area conveying subassembly includes: the conveying belt capable of moving along the conveying direction of the material belt is capable of being output, the conveying belt leaks from the opening, and the surface of the conveying belt is superposed on the surface of the material supporting platform.

8. The cross cut filler apparatus of claim 7 wherein the belt conveyor assembly further comprises: the driving device comprises two fixing plates arranged along the transverse direction, two driven transmission shafts and a main transmission shaft which are rotatably arranged between the two fixing plates, two driven wheels respectively arranged at the same ends of the two driven transmission shafts, a driving wheel arranged at the same end of a driving shaft and a driving wheel driving motor; the main transmission shaft is positioned below the two driven transmission shafts, the two driven transmission shafts are sequentially arranged along the longitudinal direction, the plane where the topmost ends of the two driven transmission shafts are located is a horizontal plane, the conveyor belt is wound on the two transmission shafts and the main transmission shaft, and the driving wheel driving motor is in transmission connection with the driving wheel and used for driving the driving wheel to rotate so as to drive the conveyor belt to rotate; the plane of the parts of the conveyor belt positioned on the two driven shafts is superposed with the surface of the material supporting platform.

9. The fully automatic multi-layer gauze packing, dicing and packing apparatus of claim 1, wherein the pressing adsorption transfer mechanism comprises: the device comprises a cantilever frame, at least two rows of pressing plate groups, a cantilever frame lifting driving assembly, a cantilever frame longitudinal driving assembly and a negative pressure switching assembly; the at least two rows of pressing plate groups are arranged on the cantilever frame and comprise a plurality of pressing plates arranged along the transverse direction, the lower surfaces of the pressing plates face downwards, a plurality of adsorption holes are uniformly distributed on the lower surfaces of the pressing plates, and the adsorption holes are communicated with the negative pressure switching assembly; the negative pressure switching assembly is used for switching the adsorption holes among negative pressure, atmospheric pressure and broken vacuum pressure; the cantilever frame lifting driving assembly is used for driving the cantilever frame to ascend or descend, and the cantilever frame longitudinal driving assembly is used for driving the cantilever frame to reciprocate in the longitudinal direction; the negative pressure switching assembly comprises: closely laminate, but and relative movement's first regulating plate and second regulating plate, be provided with three rows on the first regulating plate and adjust the punch combination, be provided with one row of connecting hole group on the second regulating plate, three rows adjust the punch combination from the top down and set gradually include: a negative pressure regulating hole group, an atmospheric pressure regulating hole group and a vacuum breaking regulating hole group; the negative pressure adjusting hole group, the atmospheric pressure adjusting hole group, the vacuum breaking adjusting hole group and the connecting hole group comprise at least two through holes with the same interval and the corresponding positions, the negative pressure adjusting hole group is externally connected with a negative pressure device generating negative pressure, the atmospheric pressure adjusting hole group is communicated with the atmosphere, and the vacuum breaking adjusting hole group is externally connected with a blowing device generating blowing force.

10. The fully automatic multi-layer gauze packing and dicing filler apparatus of claim 1, wherein the fixed-length feeding mechanism comprises: an upper pull roll, a lower pull roll, an upper pull roll drive assembly, and a pull drive assembly; the upper traction roller and the lower traction roller are arranged along the transverse direction, and the upper traction roller driving assembly is used for driving the upper traction roller to move towards or away from the lower traction roller; the traction driving assembly is used for driving the upper traction roller or the lower traction roller to intermittently rotate along the conveying direction of the material belt.