CN115008517B - Automatic cutting and trimming equipment - Google Patents

Abstract

The utility model relates to a tectorial membrane cutting technical field specifically is about an automatic cut off is repaiied neat equipment, and this automatic cut off is repaiied neat equipment and is included: the plate conveying device comprises a plate conveying plane, a pushing mechanism and a cutting mechanism, wherein the cutting mechanism comprises a cutting knife; the pushing mechanism is arranged right above the plate conveying plane and controls the sliding distance of the cutting mechanism; the cutting knife is positioned on the plate conveying plane, and the cutting direction of the cutting knife is vertical to the plate conveying plane; the transport speed of the sheet transport plane is in a functional relationship with the pushing speed of the pushing mechanism and the pushing angle of the pushing mechanism. The scheme that this application provided can realize applying the tectorial membrane on panel surface on the panel clearance integratedly and cutting, need not the board transportation plane of bring to rest to can cut the tectorial membrane on panel surface sustainedly, improved the cutting efficiency to the tectorial membrane greatly, reduced manufacturing cost simultaneously.

Description

Automatic cutting and trimming equipment

Technical Field

The application relates to the technical field of film covering and cutting, in particular to automatic cutting and trimming equipment.

Background

In the field of plate processing, a whole roll of carbon steel plate, stainless steel plate, aluminum plate and the like needs to be cut into single plates which are convenient to process, and after the single plates are subjected to surface processing such as grinding, wire drawing, embossing, titanium plating and the like, a protective film needs to be coated on the surfaces; because the protective film is continuously coated on the steel plate, a gap is inevitably generated between the former plate and the latter plate; thus, a film not applied to the surface of the plate material is generated in the gap, and at this time, the film in the portion needs to be cut and needs to be flush with the edge portion of the steel plate without leaving an excessive edge.

At present, the film which is not coated on the surface of the plate is cut off by a cutting machine at the gap, then the cut edge of the film is trimmed by an edge trimmer, and the conveying line is stopped in the process, so that the film which is not coated on the surface of the plate can be removed with high precision by the cutting machine and the edge trimmer, and the automatic cutting and trimming process of the film which is not coated on the surface of the plate is realized; the film is cut off in the mode, various devices are needed, and the conveying line needs to be stopped, so that the time spent on cutting and trimming is prolonged; especially, in the vertical direction of processing on the transport line and supplied material conveying, the multiple devices not only waste the space of the production line, but also cause the time for cutting the film of each plate to be prolonged, thereby reducing the production efficiency of work and causing the problem of film sticking quality of the plate head.

For example, in a technical solution disclosed in publication No. CN107054719A entitled "apparatus and method for laminating and cutting a film on a sheet material", a first sheet material conveying section, a second sheet material conveying section, a cutting section, and a controller are provided, and the first sheet material conveying section and the second sheet material conveying section are provided at intervals along a sheet material conveying path; when the controller detects that the gap between two adjacent plates moves to the position corresponding to the cutting part, the first plate material conveying part and the second plate material conveying part are stopped, the cutting part is controlled to move towards the gap until the preset cutting height is reached, then the cutting part is controlled to move along the extending direction of the gap until the covering film at the gap is completely cut off, the covering film in the gap is automatically cut off along the edges of the two plates, the cutting and trimming are still required to be carried out after the conveying line is stopped, the high-quality film cutting can be completely realized, and the film cannot be cut continuously.

Therefore, how to realize the automatic and integrated continuous cutting of the coating which is not applied on the surface of the plate on the plate gap is a technical problem to be solved by technicians at present.

Disclosure of Invention

For overcoming the problem that exists among the correlation technique, the application provides an automatic cut off and repair neat equipment, can realize applying the tectorial membrane on panel surface on the panel clearance integratedly and cutting, need not the board transportation plane of bring to rest moreover, can cut the tectorial membrane on panel surface continuously, improved the cutting efficiency to the tectorial membrane greatly, reduced manufacturing cost simultaneously.

In order to achieve the above object, the present application mainly adopts the following technical solution as an automatic cutting and trimming device, including:

the plate conveying device comprises a plate conveying plane, a pushing mechanism and a cutting mechanism, wherein the cutting mechanism comprises a cutting knife; the pushing mechanism is arranged right above the plate conveying plane and controls the sliding distance of the cutting mechanism; the cutting knife is positioned on the plate conveying plane, and the cutting direction of the cutting knife is vertical to the plate conveying plane; the transport speed of the sheet transport plane is in a functional relationship with the pushing speed of the pushing mechanism and the pushing angle of the pushing mechanism.

Preferably, the ratio of the transport speed to the push speed is equal to the sine of the push angle, and the push angle is an acute angle.

Preferably, the pushing mechanism comprises a transmission belt, a guide supporting rod and a servo motor; wherein, the both ends of this guide strut set up sliding gear, this drive belt and this sliding gear tooth connection, this servo motor's pivot and this sliding gear key-type connection of one end, and this cutting mechanism fixes on this drive belt.

Preferably, the cutting mechanism comprises a cutting head, a first connecting piece, a second connecting piece and a cylinder; the cutting knife is fixed on the cutting head, the cutting head is fixed on the first connecting piece, the second connecting piece is connected with the first connecting piece in a sliding way, and the second connecting piece is fixed on the pushing mechanism; the cylinder controls the longitudinal sliding distance of the first connecting piece, and the sliding direction of the first connecting piece is perpendicular to the plate conveying plane.

Preferably, the cutting head comprises a mounting box body, a guide structure and a sliding block, a first sliding guide rod and a second sliding guide rod are arranged in the mounting box body, the sliding block is respectively sleeved at two ends of the first sliding guide rod, and the second sliding guide rod is used for being parallel to the sliding block; wherein, this guide structure is fixed on this sliding block, is equipped with the spring in this first sliding guide pole, and this spring is located between this sliding block at this first sliding guide pole both ends, and this cutting knife is fixed on this sliding block.

Preferably, the plate conveying device further comprises a conveying body, the conveying body comprises at least two portal frames and a rotating roller, the two portal frames are aligned with each other, the rotating roller is uniformly arranged on a beam of the portal frames, two ends of the rotating roller are respectively connected with the beams of the two portal frames in a rotating mode, and the plate conveying plane is placed on the rotating roller.

Preferably, the guide structure comprises a first guide-in side plate, a second guide-in side plate, a first fixed side plate and a second fixed side plate, wherein the first fixed side plate and the second fixed side plate are respectively fixed on the sliding blocks at two ends; one end of the first leading-in side plate is fixedly connected with the first fixed side plate, the other end of the first leading-in side plate is hinged with one end of the second leading-in side plate, and the other end of the second leading-in side plate is fixedly connected with the second fixed side plate.

Preferably, the axis of the first sliding guide rod and the axis of the second sliding guide rod are located on the same horizontal plane.

Preferably, the bottom of the sliding block is provided with a semicircular lug, and the semicircular lug is tangent to the plate conveying plane.

Preferably, one side of the guide strut is provided with a sliding track, and the cutting mechanism is connected with the sliding track in a sliding mode.

The technical scheme provided by the application can comprise the following beneficial effects:

in the application, a pushing mechanism is arranged right above a plate conveying plane, the sliding distance of a cutting mechanism is controlled through the pushing mechanism, a cutting knife of the cutting mechanism is arranged on the plate conveying plane, the cutting direction of the cutting knife is set to be perpendicular to the plate conveying direction, then the pushing angle of the pushing mechanism is controlled, and the pushing angle is in a functional relation with the plate plane conveying speed and the pushing speed of the pushing mechanism; the pushing speed and the pushing angle of the pushing mechanism are directly linked by establishing a functional relation, so that the speed in the conveying direction of the plate conveying plane is consistent with the pushing speed in the same direction of the conveying direction of the plate conveying plane, and the relative rest of the two is realized; for example, a plate with a film is placed on a plate conveying plane to be conveyed, when a cutting knife cuts the film between plate gaps, the speed of the conveying direction of the plate conveying plane is consistent with the pushing speed (namely the cutting speed of the cutting knife) of the same direction of the conveying direction of the plate conveying plane, the two are relatively static, so that the cutting knife can be always attached to the plate, then the cutting knife on a cutting mechanism is pushed through a pushing mechanism, the film which is not applied to the surface of the plate is cut, the film which is not applied to the surface of the plate in the gap of the plate is integrally cut, the plate conveying plane does not need to be stopped, the film on the surface of the plate can be continuously cut, the cutting efficiency of the film is greatly improved, the cost for using various devices is saved, and the production cost is reduced.

It is to be understood that both the foregoing general description and the following detailed description are exemplary and explanatory only and are not restrictive of the application.

Drawings

The foregoing and other objects, features and advantages of the application will be apparent from the following more particular descriptions of exemplary embodiments of the application as illustrated in the accompanying drawings wherein like reference numbers generally represent like parts throughout the application.

Fig. 1 is a schematic structural view of an automatic cutting and trimming apparatus according to an embodiment of the present disclosure;

FIG. 2 is a schematic structural diagram of a pushing mechanism according to an embodiment of the present application;

FIG. 3 is a schematic structural diagram of a cutting mechanism according to an embodiment of the present application;

FIG. 4 is a schematic view of a cutting head according to an embodiment of the present application;

in the figure: the plate conveying device comprises a plate conveying plane-10, a pushing mechanism-20, a transmission belt-21, a guide support rod-22, a sliding track-221, a servo motor-23, a sliding gear-24, a cutting mechanism-30, a cutting knife-31, a cutting head-32, a mounting box-321, a guide structure-322, a first guide-in side plate-322 a, a second guide-in side plate-322 b, a first fixed side plate-322 c, a second fixed side plate-322 d, a sliding block-323, a first sliding guide rod-324, a second sliding guide rod-325, a spring-326, a semicircular bump-327, a first connecting piece-33, a second connecting piece-34, an air cylinder-35, a conveying body-40, a portal frame-41 and a rotating roller-42.

Detailed Description

Preferred embodiments of the present application will be described in more detail below with reference to the accompanying drawings. While the preferred embodiments of the present application are shown in the drawings, it should be understood that the present application may be embodied in various forms and should not be limited to the embodiments set forth herein. Rather, these embodiments are provided so that this disclosure will be thorough and complete, and will fully convey the scope of the disclosure to those skilled in the art.

The terminology used herein is for the purpose of describing particular embodiments only and is not intended to be limiting of the application. As used in this application and the appended claims, the singular forms "a", "an", and "the" are intended to include the plural forms as well, unless the context clearly indicates otherwise. It should also be understood that the term "and/or" as used herein refers to and encompasses any and all possible combinations of one or more of the associated listed items.

It will be understood that when an element is referred to as being "secured to" or "disposed on" another element, it can be directly on the other element or be indirectly on the other element. When an element is referred to as being "connected to" another element, it can be directly connected to the other element or be indirectly connected to the other element.

In the description of the present application, it is to be understood that the terms "thickness," "upper," "lower," "front," "back," "vertical," "horizontal," "top," "bottom," "inner," "outer," and the like are used in the orientations and positional relationships indicated in the drawings for the purpose of convenience in describing the application and simplifying the description, and are not intended to indicate or imply that the referenced device or element must have a particular orientation, be constructed and operated in a particular orientation, and thus should not be construed as limiting the application.

In the description of the present application, it should be noted that, unless otherwise explicitly stated or limited, the terms "mounted," "connected," and "connected" are to be construed broadly, and may be, for example, a fixed connection, a detachable connection, or an integral connection; can be mechanically or electrically connected; either directly or indirectly through intervening media, either internally or in any other relationship. The specific meaning of the above terms in the present application can be understood by those of ordinary skill in the art as the case may be.

Referring to fig. 1 to 4, the automatic cutting and trimming apparatus includes:

the plate conveying device comprises a plate conveying plane 10, a pushing mechanism 20 and a cutting mechanism 30, wherein the cutting mechanism 30 comprises a cutting knife 31; the pushing mechanism 20 is arranged right above the plate material conveying plane 10 and controls the sliding distance of the cutting mechanism 30; the cutting knife 31 is positioned on the plate conveying plane 10, and the cutting direction of the cutting knife 31 is perpendicular to the direction of the plate conveying plane 10; the transport speed of the sheet transport plane 10 is a function of the pushing speed of the pushing mechanism 20 and the pushing angle of the pushing mechanism 20.

In particular, the ratio of the transport speed to the pushing speed is equal to the sine of the pushing angle, and the pushing angle is an acute angle.

Specifically, the pushing mechanism 20 comprises a transmission belt 21, a guide supporting rod 22 and a servo motor 23; sliding gears 24 are arranged at two ends of the guide support rod 22, the transmission belt 21 is in toothed connection with the sliding gears 24, a rotating shaft of the servo motor 23 is in key connection with the sliding gears 24 at one end, and the cutting mechanism 30 is fixed on the transmission belt 21.

Specifically, the cutting mechanism 30 includes a cutting head 32, a first connecting member 33, a second connecting member 34, and a cylinder 35; the cutting knife 31 is fixed on the cutting head 32, the cutting head 32 is fixed on the first connecting piece 33, the second connecting piece 34 is connected with the first connecting piece 33 in a sliding manner, and the second connecting piece 34 is fixed on the pushing mechanism 20; wherein the cylinder 35 controls the longitudinal sliding distance of the first connecting member 33, and the sliding direction of the first connecting member 33 is perpendicular to the plate transportation plane 10.

Specifically, the cutting head 32 includes a mounting case 321, a guiding structure 322 and a sliding block 323, a first sliding guide rod 324 and a second sliding guide rod 325 are disposed in the mounting case 321, the sliding block 323 is respectively sleeved at two ends of the first sliding guide rod 324, and the second sliding guide rod 325 is used for being parallel to the sliding block 323; the guiding structure 322 is fixed on the sliding blocks 323, a spring 326 is disposed in the first sliding guide rod 324, the spring 326 is located between the sliding blocks 323 at two ends of the first sliding guide rod 324, and the cutting blade 31 is fixed on the sliding blocks 323.

Specifically, the plate conveying device further comprises a conveying body 40, wherein the conveying body 40 comprises at least two portal frames 41 and rotating rollers 42, the two portal frames 41 are aligned with each other, the rotating rollers 42 are uniformly arranged on the cross beams of the portal frames 41, two ends of each rotating roller 42 are respectively connected with the cross beams of the two portal frames 41 in a rotating mode, and the plate conveying plane 10 is placed on the rotating rollers 42.

Specifically, the guide structure 322 includes a first leading-in side plate 322a, a second leading-in side plate 322b, a first fixed side plate 322c and a second fixed side plate 322d, and the first fixed side plate 322c and the second fixed side plate 322d are respectively fixed on the sliding blocks 323 at two ends; one end of the first leading-in side plate 322a is fixedly connected to the first fixing side plate 322c, the other end of the first leading-in side plate is hinged to one end of the second leading-in side plate 322b, and the other end of the second leading-in side plate 322b is fixedly connected to the second fixing side plate 322 d.

Specifically, the axis of the first sliding guide 324 and the axis of the second sliding guide 325 are located on the same horizontal plane.

Specifically, a semicircular bump 327 is disposed at the bottom of the sliding block 323, and the semicircular bump 327 is tangent to the plate transportation plane 10.

Specifically, one side of the guide strut 22 is provided with a sliding track 221, and the cutting mechanism 30 is slidably connected with the sliding track 221.

Example one

In the embodiment, in order to realize continuous cutting of a coating which is not coated on the surface of a plate on a plate gap in an automatic and integrated manner, the pushing mechanism is arranged right above a plate conveying plane, the sliding distance of the cutting mechanism is controlled by the pushing mechanism, a cutting knife of the cutting mechanism is arranged on the plate conveying plane, meanwhile, the cutting direction of the cutting knife is set to be vertical to the plate conveying direction, then, the pushing angle of the pushing mechanism is controlled, and the pushing angle, the plate conveying speed and the pushing speed of the pushing mechanism form a functional relationship; the pushing speed and the pushing angle of the pushing mechanism are directly linked by establishing a functional relation, so that the speed in the conveying direction of the plate conveying plane is consistent with the pushing speed in the same direction of the conveying direction of the plate conveying plane, and the relative rest of the two is realized; when the cutting machine is used for cutting, the speeds in the same direction are consistent, the cutting knife can synchronously cut along the conveying direction of the plate conveying plane, and the phenomenon of mutual blocking cannot occur, so that the coating film in the plate gap can be cut or trimmed, and the coating film which is not coated on the surface of the plate in the plate gap can be continuously cut integrally; for example:

the embodiment places the plate with the film on the plate conveying plane for conveying, when the cutting knife cuts the film between the plate gaps, the speed of the conveying direction of the plate conveying plane is consistent with the pushing speed (namely the cutting speed of the cutting knife) of the same direction of the conveying direction of the plate conveying plane, and the two are relatively static, so that the cutting knife can be always attached to the plate, then the cutting knife on the cutting mechanism is pushed by the pushing mechanism to cut the film which is not applied on the surface of the plate, on the basis of continuous conveying of the plate conveying plane, the film which is not applied on the surface of the plate on the plate gaps can be integrally cut, the plate conveying plane does not need to stop running, the film on the surface of the plate can be continuously cut, the cutting efficiency of the film is greatly improved, the cost for using various devices is saved, and the production cost is reduced.

In addition, the pushing angle of the pushing mechanism refers to an included angle formed between the pushing direction of the pushing mechanism and the side edge of the gap of the plate; specifically, because the speed is a vector, the defect that the existing plate needs to be stopped when cutting and laminating the plate is avoided and the cutting efficiency is improved by changing the pushing direction of the pushing mechanism and controlling the pushing speed of the pushing mechanism and the conveying speed of the plate conveying plane; the ratio of the conveying speed to the pushing speed is set to be equal to the sine value of the pushing angle, the pushing angle is set to be an acute angle, and by controlling the relationship of the conveying speed, the pushing speed and the pushing speed, the film covering on the gap of the plate can be effectively cut by using the cutting knife without errors; for example, the pushing angle is set to 30 degrees, namely, the included angle formed by the pushing direction of the pushing mechanism and the side edge of the plate gap is set to 30 degrees, then the pushing speed value of the pushing mechanism and the conveying speed value of the plate conveying plane are set through a trigonometric function relation, and due to the existence of the pushing angle, the pushing speed of one side in the same direction with the plate conveying plane is consistent with the conveying speed of the plate conveying plane, and in the cutting process, the pushing angle and the conveying speed value are relatively static, so that the cutting knife can accurately cut or trim the coating film of the plate gap which is continuously conveyed.

It should be noted that, the pushing mechanism in this example is composed of a transmission belt, a guide rod, a servo motor and other components; the cutting mechanism is fixed on the transmission belt, and the speed control of the transmission belt can be realized by controlling the rotating speed of the servo motor; specifically, the arrangement direction of the guide support rod is controlled, namely the guide support rod is arranged above the plate conveying plane, and an included angle formed by the axis of the guide support rod and the side edge of the plate gap is consistent with the above-mentioned pushing angle, so that automatic cutting of the plate coating and continuous cutting of the plate coating can be realized; in addition, in order to improve the transmission belt and stably drive the cutting mechanism to push and cut, one side of the guide supporting rod is provided with a sliding rail, and the cutting mechanism is connected with the sliding rail in a sliding mode.

It is worth noting that in order to solve the problem of how to automatically reset the cutting mechanism, the cutting mechanism comprises a cutting head, a first connecting piece, a second connecting piece, a cylinder and the like; wherein the cutting knife is fixed on the cutting head, the cutting head is fixed on the first connecting piece, the second connecting piece is connected with the first connecting piece in a sliding way, and the second connecting piece is fixed on a transmission belt of the pushing mechanism; the sliding gear is rotated by the servo motor to drive the transmission belt to carry out transmission, the second connecting piece is driven by the transmission belt to change the position of the second connecting piece, meanwhile, the first connecting piece which is connected with the second connecting piece in a sliding way is driven, and finally, the cutting knife on the cutting head is driven by the first connecting piece to carry out cutting; in addition, in order to achieve automatic reset after the film covering of the plate gap is cut once and not affect the transportation of the plate transportation plane, the air cylinder is adopted to control the longitudinal sliding distance of the first connecting piece, the sliding direction of the first connecting piece is set to be perpendicular to the plate transportation plane, so that after the film covering is cut, the first connecting piece is pulled up through the air cylinder, the cutting knife on the cutting head is further pulled up, the cutting knife is far away from the plate transportation plane, then the cutting mechanism is returned to the original cutting starting position through the reverse rotation of the servo motor, the first connecting piece is lowered through the air cylinder, the transmission belt is rotated, and the cutting is performed again, and therefore the continuous cutting of the film covering of the plate gap is achieved without hindrance, and the cutting efficiency is further improved.

In practical application, in order to enhance the practicability of the device, the device in this example further comprises a transportation body, namely, the plate transportation plane is located on the transportation body, specifically, the transportation body comprises at least two portal frames and a rotating roller, the two portal frames are aligned with each other to realize parallel, then the rotating roller is uniformly arranged on a cross beam of the portal frames, and two ends of the rotating roller are respectively connected with two cross beams of the portal frames in a rotating manner, so that the rotating roller is arranged on the cross beam to rotate, and the axes of all the rotating rollers are located on the same horizontal plane, so that the plate transportation plane is flat, the plate transportation plane can stably transport plates, and the cutting knife can conveniently cut the plates.

Example two

In the embodiment, because the film which is not coated on the surface of the plate is generated at the gap of the plate, the film at the part needs to be cut off and needs to be flush with the edge of the steel plate, and no redundant edge is left; in order to overcome the above-mentioned problems, the present embodiment specifically proposes a solution to the problem, and describes and reveals a technical solution.

Therefore, in the present embodiment, the cutting head is composed of a mounting box, a guiding structure, sliding blocks and the like, a first sliding guide rod and a second sliding guide rod are arranged in the mounting box, the sliding blocks are respectively sleeved at two ends of the first sliding guide rod, so that the two sliding blocks are sleeved on the first sliding guide rod to slide, and the second sliding guide rod is sleeved at the other end of the sliding block, so that the sliding blocks can be kept stable in the mounting box, and the two sliding blocks can slide on the first sliding guide rod; the cutting device comprises a sliding block, a cutting knife, a guide structure and a spring, wherein the guide structure and the cutting knife are fixed on the sliding block, the spring is arranged in the first sliding guide rod between the sliding blocks at two ends, the sliding blocks at two ends are pushed and pressed onto side plates in an installation box body through the spring, when the cutting is carried out, the cutting knife is sleeved in a plate gap through the guide structure fixed on the sliding block, the distance between the plate gap and the sliding guide rod is smaller than the length of the first sliding guide rod, the plate enters the plate gap, the sliding block can be pushed to be tightened in the sliding guide rod, meanwhile, the spring compresses two sides of the plate gap through the pushing and pressing sliding block, the cutting knife on the sliding block is compressed on two sides of the plate gap, the butt joint with the side edge of the plate is realized, when the cutting mechanism pushes the cutting mechanism, the cutting knife and the two sides of the plate gap are compressed for cutting, and the precision removal of a coating film which is not applied on the surface of the plate is realized.

It is worth noting that due to the fact that the plate gap is short, in order to enable the cutting knife to smoothly enter the gap between the plates to cut the coating, the cutting knife is guided into the plate gap by introducing the guide structure through the head of the guide structure, and then the cutting knife is abutted against the side edge of the plate gap through the spring on the first sliding guide rod, so that accurate cutting and trimming are achieved; specifically, the guide structure is arranged to be composed of a first guide-in side plate, a second guide-in side plate, a first fixed side plate and a second fixed side plate, wherein the first fixed side plate and the second fixed side plate are respectively fixed on the sliding blocks at two ends, one end of the first guide-in side plate is fixedly connected with the first fixed side plate, the other end of the first guide-in side plate is hinged with one end of the second guide-in side plate, and the other end of the second guide-in side plate is fixedly connected with the second fixed side plate, so that a conical guide head is formed at the joint of the first guide-in side plate and the second guide-in side plate; when cutting is carried out, the cutting knife enters the plate gap through the conical guide head, then the whole cutting mechanism is pushed to slide, the plate gap compresses the sliding blocks on the sliding guide rod due to the fact that the length of the plate gap is different from that of the sliding guide rod of the cutting head, the sliding blocks on the two sides move towards the center, meanwhile, due to the existence of the spring, the sliding blocks are compressed on the two sides of the plate gap by force, abutting is achieved, and then the cutting knife fixed on the sliding blocks can be attached to the two sides of the plate gap, and the coated film which is not coated on the surface of the plate can be cut tightly; simultaneously after the cutting is accomplished, can also carry out automatically through the spring and recover, cut once more, realize automaticly.

It should be noted that, in order to ensure that the sliding blocks are kept parallel in the installation box body, the axis of the first sliding guide rod and the axis of the second sliding guide rod are arranged to be positioned on the same horizontal plane, so as to ensure that the cutting knife cannot displace; in addition, in order to improve the precision of the cutting of the coating, the semicircular lug is arranged at the bottom of the sliding block, and the coating is compressed through the semicircular lug, so that the cutting knife is prevented from tearing the coating when cutting the coating, the cutting coating is prevented from deforming, and the cutting quality of the cutting coating is prevented from being influenced; the semicircular lug is required to be tangent to the plate conveying plane so as to prevent the smoothness of cutting.

In conclusion, the automatic cutting and trimming equipment can continuously cut and modify the film covering at the gap of the plate material with high quality, greatly improves the cutting efficiency of the film covering at the gap of the plate material, and reduces the production cost.

The solution of the present application has been described in detail hereinabove with reference to the drawings. In the foregoing embodiments, the descriptions of the respective embodiments have respective emphasis, and for parts that are not described in detail in a certain embodiment, reference may be made to the related descriptions of other embodiments. Those skilled in the art should also appreciate that the acts and modules referred to in the specification are not necessarily required in the present application. In addition, it can be understood that the steps in the method of the embodiment of the present application may be sequentially adjusted, combined, and deleted according to actual needs, and the modules in the device of the embodiment of the present application may be combined, divided, and deleted according to actual needs.

Having described embodiments of the present application, the foregoing description is intended to be exemplary, not exhaustive, and not limited to the disclosed embodiments. Many modifications and variations will be apparent to those of ordinary skill in the art without departing from the scope and spirit of the described embodiments. The terminology used herein is chosen in order to best explain the principles of the embodiments, the practical application, or improvements made to the technology in the marketplace, or to enable others of ordinary skill in the art to understand the embodiments disclosed herein.

Claims (8)

1. An automatic cut-off trim apparatus, comprising:

the plate cutting machine comprises a plate conveying plane, a pushing mechanism and a cutting mechanism, wherein the cutting mechanism comprises a cutting knife, a cutting head, a first connecting piece, a second connecting piece and a cylinder; the cutting knife is fixed on the cutting head, the cutting head is fixed on the first connecting piece, the second connecting piece is connected with the first connecting piece in a sliding mode, and the second connecting piece is fixed on the pushing mechanism; the cylinder controls the longitudinal sliding distance of the first connecting piece, and the sliding direction of the first connecting piece is perpendicular to the plate conveying plane; the pushing mechanism is arranged right above the plate conveying plane and controls the sliding distance of the cutting mechanism;

the cutting knife is positioned on the plate conveying plane, and the cutting direction of the cutting knife is vertical to the plate conveying plane; the cutting head comprises a mounting box body, a guide structure and sliding blocks, a first sliding guide rod and a second sliding guide rod are arranged in the mounting box body, the sliding blocks are respectively sleeved at two ends of the first sliding guide rod, and the second sliding guide rod is used for being parallel to the sliding blocks; the guide structure is fixed on the sliding blocks, a spring is arranged in the first sliding guide rod and positioned between the sliding blocks at two ends of the first sliding guide rod, and the cutting knife is fixed on the sliding blocks; the transport speed of the sheet transport plane is in a functional relationship with the pushing speed of the pushing mechanism and the pushing angle of the pushing mechanism.

2. An automatic cut-off trim apparatus according to claim 1, wherein a ratio of the transport speed to the push speed is equal to a sine of the push angle, and the push angle is an acute angle.

3. An automatic cutting and trimming device according to claim 1, wherein the pushing mechanism comprises a transmission belt, a guide supporting rod and a servo motor; the two ends of the guide supporting rod are provided with sliding gears, the transmission belt is connected with the sliding gear teeth, the rotating shaft of the servo motor is connected with the sliding gear key at one end, and the cutting mechanism is fixed on the transmission belt.

4. The automatic cutting and trimming device according to claim 2, further comprising a transporting body, wherein the transporting body comprises at least two portal frames and a rotating roller, the two portal frames are aligned with each other, the rotating roller is uniformly arranged on the beams of the portal frames, two ends of the rotating roller are respectively and rotatably connected with the beams of the two portal frames, and the plate transporting plane is placed on the rotating roller.

5. An automatic cutting and trimming device according to claim 1, wherein the guide structure includes a first guide-in side plate, a second guide-in side plate, a first fixed side plate and a second fixed side plate, the first fixed side plate and the second fixed side plate being fixed to the slide blocks at both ends, respectively; one end of the first leading-in side plate is fixedly connected with the first fixed side plate, the other end of the first leading-in side plate is hinged to one end of the second leading-in side plate, and the other end of the second leading-in side plate is fixedly connected with the second fixed side plate.

6. An automatic cut-off trim apparatus according to claim 1, wherein the axis of said first slide guide and the axis of said second slide guide are located on the same horizontal plane.

7. An automatic cut-off trim apparatus as claimed in claim 1, wherein the bottom of said sliding block is provided with a semicircular projection, and said semicircular projection is tangent to said plate transport plane.

8. An automatic cut-off trim apparatus according to claim 3, wherein a sliding rail is provided on one side of the guide bar, and the cutting mechanism is slidably connected to the sliding rail.

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