CN211053880U - Feeding blank device and including device's cutting rigging machine - Google Patents

Abstract

The utility model discloses a feeding and cutting device and a cutting laminating machine comprising the same, comprising a first feeding roller, a second feeding roller and a punching assembly, wherein the second feeding roller is arranged above the first feeding roller; the first feeding roller and/or the second feeding roller are/is in transmission connection with a second rotating power mechanism, the first feeding roller and the second feeding roller can clamp the raw material belt, and the second rotating power mechanism can control the feeding of the raw material belt to the punching assembly. Compared with the prior art that the raw material belt is fed at the rear end of the punching assembly in a pulling mode, the feeding device has higher precision; specifically, the two feeding rollers are used for clamping and pushing, a certain amount of raw material belts can not be fed into the punching assembly independently due to the flexibility of the raw material belts, and the raw material belts between the feeding rollers and the punching assembly are tight and can not generate feeding redundancy errors.

Description

Feeding blank device and including device's cutting rigging machine

Technical Field

The utility model relates to a membrane processing especially relates to a feeding blank device.

Background

In some electrical components such as circuit boards or lithium batteries, a layer of silica gel film is required to be adhered to the outer surface of the electrical components, and the lower end of the silica gel film is adhered to the circuit boards or the electrical components through a UV (ultraviolet) adhesive layer of the silica gel film. According to the speed of the condensation and adhesion rate of the thermalized viscose glue, different UV glue layers are required to be selected.

In the technology for sticking the silicone membrane on the circuit board or the electrical element, the front end is generally provided with a roll of raw material belt, the raw material belt comprises a mother belt and the silicone membrane, and the lower end of the silicone membrane is provided with a UV station adhesive layer; the feeding roller rotates and clamps the raw material belt to drive the raw material to feed and feed. The master tape is used for transferring materials, applying/connecting/storing materials and the like.

In the prior art, a raw material belt is pulled to feed mainly by a mode of winding a master belt; however, in this manner, the amount of feed of the strip of stock into the blanking assembly is relatively inaccurate and cannot be easily controlled effectively. The front end of the punching component is easy to have a certain loose section, and the feeding amount is possibly overlarge; meanwhile, the width of the cut silicon film is smaller and smaller due to the fact that the mother belt has certain elasticity, the linear displacement of the winding roller for winding the mother belt is larger than the feeding amount of the raw material belt, the feeding amount is possibly too small, and certain accumulated errors exist.

SUMMERY OF THE UTILITY MODEL

The utility model discloses an solve one of the technical problem that exists among the prior art at least, solve the problem that raw material belt is not accurate enough toward die-cut subassembly feed volume, the utility model discloses a technical scheme be:

according to a first aspect of the present invention, there is provided a feeding and blanking device, comprising a first feeding roller, a second feeding roller and a punching assembly, wherein the second feeding roller is arranged above the first feeding roller; the first feeding roller and/or the second feeding roller are/is in transmission connection with a second rotating power mechanism, the first feeding roller and the second feeding roller can clamp a raw material belt, and the second rotating power mechanism can control the raw material belt to feed to the punching assembly.

Has the advantages that: compared with the prior art that the raw material belt is fed at the rear end of the punching assembly in a pulling mode, the feeding device has higher precision; specifically, the two feeding rollers are used for clamping and pushing, a certain amount of raw material belts can not be fed into the punching assembly independently due to the flexibility of the raw material belts, and the raw material belts between the feeding rollers and the punching assembly are tight and can not generate feeding redundancy errors.

Preferably, the punching assembly comprises an upper template and a lifting power piece for driving the upper template to lift; the lower end of the upper template is provided with a cutter.

Preferably, the lower end of the upper template is also provided with an elastic pressing device; the cutter can be lifted when the lower end of the elastic pressing device elastically supports against the raw material belt.

Preferably, the elastic pressing device comprises a guide part, a pressing block and an elastic part, the guide part is connected with the upper template, and the pressing block and the elastic part are both connected with the guide part; the elastic piece can drive the lower end of the pressing block to be lower than the lower end of the cutter, and the pressing block can move upwards relative to the guide piece and compress the elastic piece.

Preferably, the upper die plate is connected with a return spring, and the return spring is used for driving the upper die plate to return upwards.

Preferably, the punching assembly comprises a base, a guide rod penetrates through the base, the upper end of the guide rod is connected with an upper template, the lower end of the guide rod is connected with a lifting plate, the lifting power part is used for driving the lifting plate to lift, and a return spring is connected between the lifting plate and the base.

A cutting laminating machine comprises the feeding and cutting device, a pre-feeding assembly, a first platform, a second platform and a transfer device; the pre-feeding assembly can drive the raw material belt to be cached between the pre-feeding assembly and the first feeding roller; first material loading roller, die-cut subassembly and first platform set gradually along material transmission direction, and the die-cut subassembly can cut off the membrane spare on the raw materials area, and the gap between first platform and the second platform can let the master tape in the raw materials area pass, and the second platform can cache the membrane spare in raw materials area, and transfer device can shift the membrane spare on the second platform.

Has the advantages that: the front end of the punching assembly is fed with the raw material belt in a pinch advancing mode, the raw material belt with a certain length is fed at a single time in an adjustable mode according to the width of a film piece required by a product, the feeding of the raw material belt is accurate, the obtained relatively accurate film piece is transferred, the feeding and cutting can be continuously and quickly executed, the film piece is transferred, and the efficiency and the cost are high.

Preferably, the material heating device further comprises a heating component, the heating component is arranged above and/or below the first platform, and the heating component can heat the material on the first platform.

Preferably, the heat generating component comprises a UV lamp.

Preferably, the UV lamp is disposed below the first stage; the first stage may transmit light of a UV lamp.

Drawings

Fig. 1 is a first schematic structural view of a three-dimensional viewing angle of a cutting laminator according to an embodiment of the present invention;

fig. 2 is a schematic structural view of a three-dimensional viewing angle of a cutting laminator according to an embodiment of the present invention;

FIG. 3 is a schematic structural view of a side view angle of a cutting laminator according to an embodiment of the present invention;

fig. 4 is a schematic structural view of a three-dimensional view angle of a feeding and blanking device according to an embodiment of the present invention;

fig. 5 is a schematic structural view of a three-dimensional view angle of a feeding device in an embodiment of the present invention;

fig. 6 is a first schematic structural view of a main viewing angle of the feeding device according to the embodiment of the present invention;

fig. 7 is a second schematic structural view of the feeding device according to the embodiment of the present invention;

fig. 8 is a schematic structural view of a side view angle of a feeding device according to an embodiment of the present invention;

FIG. 9 is a schematic structural view of a stopper according to an embodiment of the present invention;

FIG. 10 is an exploded view of a stopper according to an embodiment of the present invention;

fig. 11 is a schematic structural view of an upper template and a connecting mechanism thereof according to an embodiment of the present invention;

fig. 12 is a first schematic structural diagram of a transfer device according to an embodiment of the present invention;

fig. 13 is a second schematic structural view of a transfer device according to an embodiment of the present invention;

wherein the reference numerals:

the punching device comprises a roller 100, a raw material belt 200, a film piece 200a, a mother belt 200b, a bracket 11, a notch 11a, a first rotating power mechanism 12, a first motor 121, a driving gear 122, a driven gear 123, a raw material roller 124, a first guide roller 13, a second guide roller 14, a first feeding roller 15, a second feeding roller 16, a second rotating power mechanism 17, a first limiting piece 181, a second limiting piece 182, a bottom block 18a, a rolling ball 18b, an end cover 18c, a punching assembly 2, an upper template 21, a lifting power piece 22, a cutter 23, an elastic pressing device 24, a guide piece 241, a pressing piece 242, an elastic piece 243 and a return spring 25; the lifting plate 26, the base 27, the first platform 31; the device comprises a second platform 32, a winding roller 33, a transfer device 4, a heating assembly 5, a first detection piece 6, a first imaging detection device 71, a second imaging detection device 72 and a transmission assembly 8.

Detailed Description

The following detailed description of the embodiments of the present invention will be made with reference to the accompanying drawings. For convenient feeding, the starting end of the raw material belt 200 is a section of mother belt 200b without the membrane piece 200 a; the section of the master tape 200b passes through the feeding device, the punching assembly 2 and the first platform 31, and then passes through a gap between the first platform 31 and the second platform 32, so that the supplementary installation of new raw materials is completed. In a less preferred arrangement, an end of the film member 200a is peeled off from the starting end of the raw material tape 200, and the film member 200a is wasted, thereby obtaining a mother tape 200b without the film member 200 a.

As shown in fig. 1 to 3, a cutting laminator comprises a frame, a feeding device, a punching assembly 2, a first platform 31, a second platform 32, a transfer device 4 and a transmission assembly 8; the feeding device, the punching assembly 2 and the first platform 31 are sequentially arranged along the material conveying direction, the punching assembly 2 can cut off the film piece 200a of the raw material belt 200, a gap between the first platform 31 and the second platform 32 can allow the mother belt 200b in the raw material belt 200 to pass through, and the second platform 32 can cache the film piece 200a of the raw material belt 200; the transfer device 4 can transfer the film on the second platform 32200a are transferred to the product of the transfer unit 8. The feeding direction of the raw material belt 200 is V as shown in FIGS. 1 and 3₁And V₂And (4) direction.

The frame can be arranged into a plurality of parts according to the distribution of the parts of the cutting laminating machine.

The using method of the cutting laminating machine comprises the following steps: setting, according to the width B of the film piece 200a required by the product, the length S of feeding the raw material belt 200 to the punching assembly 2 once and the time interval T of two adjacent downward blanks of the punching assembly 2; feeding, wherein the raw material belt 200 is fed to the punching assembly 2, and the film piece 200a in the raw material belt 200 is arranged above and the mother belt 200b is arranged below; cutting the film, after feeding the raw material tape 200 of the length of S to the punching assembly 2 once, stopping feeding to the punching assembly 2, and cutting the film piece 200a in the raw material tape 200 downwards by the punching assembly 2 without cutting the mother tape 200 b; the film piece 200a is buffered and comes out of the master tape 200b, the raw tape 200 is continuously fed to the punching assembly 2, the raw tape 200 can push the cut film piece 200a to pass through the first platform 31 and buffer the film piece to the second platform 32, and the master tape 200b is led out through a gap between the first platform 31 and the second platform 32; the transfer device 4 can drive the film member 200a on the second platform 32 to be transferred and applied to the product.

In the feeding device, the raw material belt 200 may be fed up only by the first feeding roller 15; that is, the feeding device may not be provided with the second feeding roller 16. The raw material belt 200 is placed on the first feeding roller 15, and the raw material belt 200 is fed to the punching assembly 2 when the first feeding roller 15 rotates; in this way, the first feeding roller 15 is moved under the raw material belt 200 by friction, and the amount of slip and the amount of feed may not be easily controlled.

In the feeding device, the buffered material tape 200 is fed in the direction of the first feeding roller 15.

In the feeding device, the following steps are also possible: in the feeding step, the raw material belt 200 is fed to the punching assembly 2 through a feeding device; as shown in fig. 1 to 3 and 5, the feeding device includes a first feeding roller 15 and a second feeding roller 16, the first feeding roller 15 and/or the second feeding roller 16 is/are connected to a second rotating power mechanism 17 in a transmission manner, and the first feeding roller 15 and the second feeding roller 16 can clamp the raw material belt 200; the second rotary power mechanism 17 controls the feed of the strip of material 200 to the blanking assembly 2. The feeding amount is controllable, and the starting and stopping of feeding are naturally controllable. Preferably, one of the first feeding roller 15 and the second feeding roller 16 is connected to a second rotary power mechanism 17, and the other is connected to an upper and lower power member 19, so that the two feeding rollers can clamp or release the raw material belt.

As shown in fig. 4, the first feeding roller 15, the second feeding roller 16, the second rotational power mechanism 17 and the punching assembly 2 can form a feeding and cutting device. The second rotating power mechanism 17 may be a motor, and the motor drives the first feeding roller 15 and/or the second feeding roller 16.

The method also comprises a pre-feeding step, wherein the feeding device also comprises a pre-feeding assembly; the pre-loading assembly may drive the stock tape 200 to buffer between the pre-loading assembly and the first loading roller 15. The first rotary power mechanism 12 drives the raw material tape buffer in the direction V as shown in FIGS. 3 and 5₁Direction; the second rotary power mechanism 17 feeds the buffered material strip to the punching assembly in the direction of feed V as shown in fig. 3 and 5₂And (4) direction.

As shown in fig. 1 to 3 and 5, the pre-feeding assembly includes a bracket 11, a first rotating power mechanism 12 and a first guide roller 13 are disposed on the bracket 11, the bracket 11 can be provided with a raw material roller 100, the first rotating power mechanism 12 can drive the raw material roller 100 to rotate and buffer a raw material belt 200 of the raw material between the first guide roller 13 and the first feeding roller 15, and the first guide roller 13 and the first feeding roller 15 can suspend two ends of the buffered raw material belt 200. In the setting step, the buffer amount of the single feed of the first rotating power mechanism 12 is set based on the power of the second rotating power mechanism 17. At the raw material position, the raw material self roller 100 is driven by the motor to rotate to pre-feed, so that the deformation and the smaller stress of the raw material belt 200 fed in a pulling and pulling manner can not be caused; first material loading roller 15 is as the most direct part of material loading, only needs to spend less interior raw materials area 200 of uploading this buffer memory, and the motor that first material loading roller 15 is connected need not great power, raw materials area 200 also indeformable, and the pinch of later stage is taken 200 modes minimumly, do not have raw materials and take 200 deformations, and raw materials area 200 feeds the precision better.

The first guide roller 13 is connected to a second detecting member which can detect the amount of the raw material belt 200 fed by the first rotating power mechanism 12. The second detecting element feeds back the buffer amount, checks the set value, and detects and corrects the buffer amount, the corresponding action of the first rotating power mechanism 12, the forward rotation, the reverse rotation, the linear displacement of the rotation, and the like. The second detecting member may be an encoder, an electromagnetic detecting piece, or the like.

As shown in fig. 6 and 8, the first rotational power mechanism 12 may be configured to: the first rotary power mechanism 12 includes a first motor 121, a driving gear 122, a driven gear 123 and a material roller 124; the raw material roller 124 can be connected with the roller 100 of the raw material, the driven gear 123 is arranged on the raw material roller 124, and the first motor 121 is in transmission connection with the driving gear 122; the holder 11 is provided with a notch 11a for placing the material roller 124. In this arrangement, the roller 100 of stock material is a hollow shaft/cylinder or the like. The feeding step is also included, the roller 124 of the roller 100 which is connected with the raw material is penetrated by the raw material roller 124, the raw material roller 124 is arranged in the notch 11a, the driven gear 123 connected with the raw material roller 124 can be directly meshed with the driving gear 122, and the first motor 121 can drive the raw material to roll. The first motor 121 may be an electric motor (i.e., an electric motor), a hydraulic motor, a pneumatic motor, or the like.

As shown in fig. 7 and 8, the first rotational power mechanism 12 may be configured to: the bracket 11 is provided with a notch 11a for placing the raw material roller 100; the first rotary power mechanism 12 includes a first motor 121, a driving gear 122 in transmission connection with the first motor 121, and a driven gear 123 for engaging the driving gear 122; the driven gear 123 may be connected to the roller 100 of stock. In this arrangement, the raw material roller 100 is a hollow shaft or a solid shaft, and the raw material roller 100 is already provided at the factory of the upstream manufacturer and can be assembled with the driven gear 123. The method also comprises a material supplementing step, wherein the driven gear 123 is sleeved on the raw material roller 100, then the raw material roller 100 is placed in the notch 11a, the driven gear 123 on the raw material roller 100 can be directly engaged with the driving gear 122, and the first motor 121 can drive the raw material to roll.

As shown in fig. 6 and 7, and fig. 9 and 10, the feeding device further includes a stopper for limiting the movement of the raw material along the axial direction of the material roller 100. The stopping means includes a first stopper 181 and a second stopper 182, the first stopper 181 and the second stopper 182 being disposed on the inner side wall of the holder 11, the first stopper 181 and the second stopper 182 being directed to both sides of the raw material, respectively. The first stopper 181 and the second stopper 182 each include a bottom block 18a, a ball 18b, and an end cap 18c, the bottom block 18a is connected with the inner side wall of the bracket 11, the bottom block 18a is provided with a recess 18d for connecting the ball 18b, the end cap 18c is used for locking the ball 18b in the recess 18d, and the end cap 18c is further provided with a through hole for the ball 18b to protrude outwards.

The stop means may also simply be an upper cover which is inverted U-shaped.

As shown in fig. 1 to 3 and 5, a second guide roller 14 disposed above the first guide roller 13 is further included, and a raw material belt 200 of raw material may pass through a gap between the first guide roller 13 and the second guide roller 14; the raw material belt 200 may be confined between the first guide roller 13 and the second guide roller 14.

As shown in fig. 3 and 5, the method further comprises a step of adjusting the minimum buffer storage amount, and adjusting the installation height of the first detection member 6 according to the B value, wherein the first detection member 6 is arranged between the first guide roller 13 and the first feeding roller 15, the first detection member 6 can detect whether the middle position of the buffered raw material belt 200 between the first guide roller 13 and the first feeding roller 15 is lifted to the right position, the first detection member 6 is connected with a positioning mechanism which can adjust the installation height of the first detection member 6, the raw material belt 200 buffer storage amount L between the first guide roller 13 and the first feeding roller 15 is used for adjusting L value of the second rotating power mechanism 17 which can feed when the first rotating power mechanism 12 is started, when the middle position of the buffered raw material belt 200 is lifted to the right position, the buffered raw material belt 200 can still feed at least one B value length to the punching assembly 2, and the positioning mechanism is used for adjusting the raw material belt buffer storage amount at the moment.

The positioning mechanism can be as follows: the positioning mechanism comprises a positioning bolt, the positioning bolt is in threaded connection with the first detection piece 6, and the adjusting bolt can drive the first detection piece 6 to lift. As shown in fig. 3, the positioning mechanism may be: the positioning mechanism comprises a vertical rod and a set screw, the first detection piece 6 is connected with the vertical rod in series, the first detection piece 6 can ascend and descend along the vertical rod, and the set screw is used for driving the first detection piece 6 to be fixedly connected with the vertical rod.

As shown in FIG. 3, the amount of the stock material strip 200 between the first guide roller 13 and the first feeding roller 15 is used up when the stock material strip 200 is straight, and the length L of the stock material strip 200 between the first guide roller 13 and the first feeding roller 15₁(ii) a As shown in fig. 3, for example, a mechanical switch with a moving contact, or some other proximity switch, when the middle position of the raw material belt 200 between the first guide roller 13 and the first feeding roller 15 reaches the lowest detection point of the first detection element 6, the raw material belt 200 between the first guide roller 13 and the first feeding roller 15 has a certain amount of buffer, which can satisfy the feeding of the width of at least one film element 200a, and when the width of the at least one film element 200a is fed, the pre-feeding assembly also stores a new amount of buffer, and the second detection element has detection statistics. In the mechanical switch, the movable contact elastically rises and falls within a certain height, the contact mechanism inside the switch keeps on or off, and at least one buffer memory of the width of the membrane element 200a is also arranged in the off time even if a new buffer memory is not stored. For the proximity switch, the proximity switch can be detected within a certain range after the raw material tape 200 is lifted.

As shown in fig. 3, when the middle portion of the raw material belt 200 is raised to a certain position, the raw material belt 200 has a certain tightness, and particularly, when the first detecting member 6 is a mechanical switch including a movable contact, the first detecting member 6 can detect the tightness of the raw material belt 200. The first detection member 6 may be a proximity switch, or the like.

As shown in fig. 1, 12 and 13, a first imaging detection device 71 is connected to the transfer device 4, the first imaging detection device 71 is disposed on the transfer device 4, and the first imaging detection device 71 can perform imaging positioning detection on the film member 200a on the second platform 32 and/or the product on the transport assembly 8; the transfer device 4 firstly slides the first imaging detection device 71 to the position above the second platform 32, and the first imaging detection device 71 carries out imaging positioning detection on the film piece 200a on the second platform 32; the transfer device 4 then transfers the film member 200a on the second stage 32 to above the product; the first imaging inspection device 71 performs imaging positioning inspection on the product, and then transfers and applies the film member 200a to the product.

As shown in fig. 1 and 2, and in fig. 12 and 13, the illustrated transfer device 4 can be called a robot, both of which achieve the same technical effect for assembling the membrane onto the cell; the illustrated transfer device 4 is connected to a first imaging detection device 71. As shown in fig. 12, the transfer device 4 is shown to more closely approximate the arm of a human body, which is often commonly known as a robot arm, and the first imaging detection device 71 is connected to the end of the robot arm. As shown in fig. 13, the illustrated transfer device 4 includes more linear shaft assemblies, and may include a rotating shaft assembly to which the first imaging detector 71 is connected. As shown in fig. 13, the transfer device 4 includes an X-axis assembly, a Y-axis assembly, a Z-axis assembly and a rotating axis assembly, and the swing direction of the transferred film member is adjusted by the transfer device 4 according to the orientation angle to be applied to the film member on the product.

As shown in fig. 1, a second imaging detection device 72 is further included, and the second imaging detection device 72 is disposed on the frame. The transfer device 4 slides the first imaging detection device 71 to the position above the second platform 32, and the first imaging detection device 71 performs imaging positioning detection on the film member 200a on the second platform 32; the film member 200a is then transferred to the position above the second imaging detection device 72, and the second imaging detection device 72 performs imaging positioning detection on the film member 200 a. The second imaging detection device 72 detects the shape, orientation, and spatial position of the film member 200a, and also detects the shape of the lower end of the film member 200a, so as to detect whether the adhesive layer is contaminated or peeled off. The first imaging detection device 71 and the second imaging device each comprise a CCD camera, and the CCD camera is electrically connected to the controller/control system. CCD cameras, a prior art, image and convert light into electrical signals, store and/or transmit the electrical signals. The first imaging detection means 71 and the second imaging means each further comprise a light source.

As shown in fig. 1, 4 and 11, the punching assembly 2 includes an upper die plate 21 and a lifting power member 22 for driving the upper die plate 21 to lift; the lower end of the upper template 21 is provided with a cutter 23 and an elastic pressing device 24; the cutter 23 is lifted when the lower end of the elastic pressing device 24 elastically presses the raw material tape 200. The upper die plate 21 is lifted in the Z direction shown in fig. 4.

As shown in fig. 11, the elastic pressing device 24 can be in two modes as shown in the figure, the guiding element 241 is a guiding rod or a sleeve, and the guiding element 241 and the pressing block 242 have certain correspondence in the structure arrangement of the penetrating relation and are locked at the lower end by a nut. The elastic pressing device 24 comprises a guide 241, a pressing block 242 and an elastic member 243, wherein the guide 241 is connected with the upper die plate 21, and the pressing block 242 and the elastic member 243 are both connected with the guide 241; the elastic member 243 may drive the lower end of the pressing piece 242 to be lower than the lower end of the cutting knife 23, and the pressing piece 242 may move upward relative to the guide 241 and compress the elastic member 243.

The elastic member 243 may be a spring, a disc spring, an elastic plastic member, etc. As shown in fig. 11, the guiding element 241 may be a guiding rod or a sleeve, and the elastic element 243 is sleeved on the guiding rod or accommodated in the sleeve.

As shown in fig. 11, the lower end of the pressing piece 242 is lower than the lower end of the cutter 23 in a normal state; when the film piece 200a is punched, the pressing block 242 is firstly abutted against the film piece 200 a; then the pressing block 242 is stationary relative to the film member 200a, the cutter 23 and the guide 241 move downwards continuously, the cutter 23 cuts the film member 200a, and the elastic member 243 contracts; since the pressing block 242 elastically presses the film 200a all the time when the cutting blade 23 ascends after the film 200a is cut, the film 200a is not lifted by the friction force and the adhesion suction force, and the pressing force is gradually reduced, and finally the film 200a is not lifted by the pressing block 242.

As shown in fig. 1 and 4, a return spring 25 is connected to the upper die plate 21, and the return spring 25 is used for driving the upper die plate 21 to return upwards. The punching assembly 2 comprises a base 27, a guide rod penetrates through the base 27, the upper end of the guide rod is connected with an upper template 21, the lower end of the guide rod is connected with a lifting plate 26, a lifting power part 22 is used for driving the lifting plate 26 to lift, and a return spring 25 is connected between the lifting plate 26 and the base 27; the frame 27 may be part of a frame of a cutting laminator. The machine base 27 is a base body, which is three in fig. 4, the upper block is connected with a workbench and/or a first platform of the punching component, the middle block is mainly used for placing a motor of a lifting power part, and the lower block is a bottom plate block.

The lifting power part 22 can be a cylinder body directly connected with the lifting plate 26 or the upper die plate 21, and can be a screw-nut pair, a motor combination and the like; as shown in fig. 1, 2 and 4, the lifting power member 22 includes a screw rod connected to lift, a nut block connected to the screw rod, a belt for rotating the nut block, and a motor connected to the belt.

The cutting laminating machine further comprises a heating component 5, the heating component 5 is arranged above and/or below the first platform 31, and the heating component 5 can heat materials on the first platform 31. The heating element 5 may include a heating wire. The heating component 5 comprises a UV lamp which is arranged above and/or below the first platform 31; preferably, the UV lamp is disposed below the first platform 31, the first platform 31 is transparent to light of the UV lamp, the master tape 200b is generally made of a transparent material, and the light of the UV lamp can penetrate through the first platform 31 and the master tape 200b to irradiate the adhesive layer on the side of the film member 200a facing the master tape 200 b.

The cutting laminating machine further comprises a winding roller 33, the winding roller 33 is connected with a winding power piece, and the winding roller 33 can wind the raw material belt 200 mother belt 200b led out from the gap between the first platform 31 and the second platform 32.

The transmission assembly 8 comprises a transmission belt, a roller and a transmission power part, the transmission belt is connected with the roller, the roller is used for driving the transmission belt to rotate, and the roller is in transmission connection with the transmission power part.

Products, materials and the like, which are not the structure of the utility model; the introduction of products, materials, etc. in the claims is intended to be illustrative of structure and/or function. The roller 100 is not limited to a roller that rolls on a plane through an outer wall.

The motor, the cylinder, the hydraulic cylinder, the pump body, the air pipe and other objects may not be available in the actual sale, namely, are not sold together, and need to be purchased and assembled by a buyer; such components are those known to those skilled in the art to be required to perform the corresponding function.

In the description of the present invention, it is to be understood that the terms "center", "longitudinal", "lateral", "length", "width", "thickness", "upper", "lower", "front", "rear", "left", "right", "vertical", "horizontal", "top", "bottom", "inner", "outer", "clockwise", "counterclockwise", "axial", "radial", "circumferential", and the like, indicate the orientation or positional relationship indicated based on the drawings, and are only for convenience of description and simplification of description, but do not indicate or imply that the device or element referred to must have a particular orientation, be constructed and operated in a particular orientation, and therefore should not be construed as limiting the present invention.

Furthermore, the terms "first", "second" and "first" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance or implicitly indicating the number of technical features indicated. Thus, a feature defined as "first" or "second" may explicitly or implicitly include at least one such feature. In the description of the present invention, "a plurality" means at least two, e.g., two, three, etc., unless specifically limited otherwise.

In the present invention, unless otherwise expressly stated or limited, the terms "mounted," "connected," and "fixed" are to be construed broadly and may, for example, be fixedly connected, detachably connected, or integrally formed; may be mechanically coupled, may be electrically coupled or may be in communication with each other; they may be directly connected or indirectly connected through intervening media, or they may be connected internally or in any other suitable relationship, unless expressly stated otherwise. The specific meaning of the above terms in the present invention can be understood according to specific situations by those skilled in the art.

In the present application, unless expressly stated or limited otherwise, the first feature may be directly on or directly under the second feature or indirectly via intermediate members. Also, a first feature "on," "over," and "above" a second feature may be directly or diagonally above the second feature, or may simply indicate that the first feature is at a higher level than the second feature. A first feature being "under," "below," and "beneath" a second feature may be directly under or obliquely under the first feature, or may simply mean that the first feature is at a lesser elevation than the second feature.

In the description herein, references to the description of the term "one embodiment," "some embodiments," "an example," "a specific example," or "some examples," etc., mean that a particular feature, structure, material, or characteristic described in connection with the embodiment or example is included in at least one embodiment or example of the invention. In this specification, the schematic representations of the terms used above are not necessarily intended to refer to the same embodiment or example. Furthermore, the particular features, structures, materials, or characteristics described may be combined in any suitable manner in any one or more embodiments or examples. Furthermore, various embodiments or examples and features of different embodiments or examples described in this specification can be combined and combined by one skilled in the art without contradiction.

The above embodiments are only used for illustrating the technical solutions of the present invention and are not limited thereto, and any modification or equivalent replacement that does not depart from the spirit and scope of the present invention should be covered by the scope of the technical solutions of the present invention.

Claims (10)

1. The utility model provides a feeding blank device which characterized in that: the punching device comprises a first feeding roller, a second feeding roller and a punching assembly, wherein the second feeding roller is arranged above the first feeding roller; the first feeding roller and/or the second feeding roller are/is in transmission connection with a second rotating power mechanism, the first feeding roller and the second feeding roller can clamp a raw material belt, and the second rotating power mechanism can control the raw material belt to feed to the punching assembly.

2. A feed blanking unit according to claim 1, characterized in that: the punching assembly comprises an upper template and a lifting power piece for driving the upper template to lift; the lower end of the upper template is provided with a cutter.

3. A feed blanking unit according to claim 2, characterized in that: the lower end of the upper template is also provided with an elastic pressing device; the cutter can be lifted when the lower end of the elastic pressing device elastically supports against the raw material belt.

4. A feed blanking unit according to claim 3, characterized in that: the elastic pressing device comprises a guide piece, a pressing block and an elastic piece, the guide piece is connected with the upper template, and the pressing block and the elastic piece are both connected with the guide piece; the elastic piece can drive the lower end of the pressing block to be lower than the lower end of the cutter, and the pressing block can move upwards relative to the guide piece and compress the elastic piece.

5. A feed blanking unit according to any one of claims 2 to 4, characterized in that: the upper die plate is connected with a return spring, and the return spring is used for driving the upper die plate to reset upwards.

6. A feed blanking unit according to any one of claims 2 to 4, characterized in that: the punching assembly comprises a base, a guide rod penetrates through the base, the upper end of the guide rod is connected with an upper template, the lower end of the guide rod is connected with a lifting plate, a lifting power part is used for driving the lifting plate to lift, and a return spring is connected between the lifting plate and the base.

7. The utility model provides a cutting rigging machine which characterized in that: the feeding and blanking device comprises the feeding and blanking device as claimed in any one of claims 1 to 6, and further comprises a pre-feeding assembly, a first platform, a second platform and a transfer device; the pre-feeding assembly can drive the raw material belt to be cached between the pre-feeding assembly and the first feeding roller; the first feeding roller, the punching assembly and the first platform are sequentially arranged along the material transmission direction, the punching assembly can cut off the film piece on the raw material belt, a gap between the first platform and the second platform can enable a mother belt in the raw material belt to pass through, the second platform can cache the film piece of the raw material belt, and the transfer device can transfer the film piece on the second platform.

8. The slitting laminator according to claim 7, wherein: still including the heating element, the heating element sets up in the top and/or the below of first platform, the heating element can heat the material on the first platform.

9. The slitting laminator according to claim 8, wherein: the heating component comprises a UV lamp.

10. The slitting laminator according to claim 9, wherein: the UV lamp is arranged below the first platform; the first stage may transmit light of a UV lamp.

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