阅读说明：本技术 一种自动贴麦拉装置 (Automatic paste wheat and draw device ) 是由 费湘海 彭杰忠 于 2020-06-28 设计创作，主要内容包括：本发明公开了一种自动贴麦拉装置,包括底座、压合驱动件、下压合组件以及上压合组件,压合驱动件及下压合组件安装于底座,上压合组件安装于压合驱动件的输出端,下压合组件设有麦拉槽及插接槽,麦拉槽与插接槽连通,麦拉片收容于麦拉槽,上压合组件包括上基准块以及上压合块,上基准块以及上压合块夹持待贴麦拉的产品,压合驱动件带动上压合组件下压直至产品与麦拉片接触后并插入插接槽,使麦拉片贴合于产品表面,整个贴麦拉过程完全机械化、自动化、贴麦拉的精度高、尺寸稳定,产能高,能够保证产品质量。(The invention discloses an automatic Mylar pasting device which comprises a base, a pressing driving piece, a lower pressing assembly and an upper pressing assembly, wherein the pressing driving piece and the lower pressing assembly are arranged on the base, the upper pressing assembly is arranged at the output end of the pressing driving piece, the lower pressing assembly is provided with a Mylar groove and an insertion groove, the Mylar groove is communicated with the insertion groove, a Mylar is accommodated in the Mylar groove, the upper pressing assembly comprises an upper reference block and an upper pressing block, the upper reference block and the upper pressing block clamp a product to be Mylar pasted, the pressing driving piece drives the upper pressing assembly to press downwards until the product is contacted with the Mylar and then is inserted into the insertion groove, so that the Mylar is pasted on the surface of the product, the whole Mylar pasting process is completely mechanized and automated, the Mylar pasting precision is high, the size is stable, the productivity is high, and the product quality can be ensured.)

1. The utility model provides an automatic paste wheat and draw device, includes the base, its characterized in that: the automatic Mylar pasting device further comprises a pressing driving piece, a lower pressing assembly and an upper pressing assembly, the pressing driving piece and the lower pressing assembly are mounted on the base, the upper pressing assembly is mounted at the output end of the pressing driving piece, the lower pressing assembly is provided with a Mylar groove and an insertion groove, the Mylar groove is communicated with the insertion groove, the Mylar is contained in the Mylar groove, the upper pressing assembly comprises an upper reference block and an upper pressing block, the upper reference block and the upper pressing block clamp a product to be pasted with Mylar, and the pressing driving piece drives the upper pressing assembly to press downwards until the product is in contact with the Mylar and then inserted into the insertion groove, so that the Mylar is pasted on the surface of the product.

2. The automated mylar applicator of claim 1, wherein: the upper pressing block comprises a sliding block, the sliding block is provided with a sliding groove, the upper reference block comprises an upper reference main body and a clamping driving piece, the clamping driving piece is installed on the upper reference main body, the upper reference main body comprises a sliding rail, the sliding rail is contained in the sliding groove, and the clamping driving piece enables the upper reference block to slide relative to the upper pressing block.

3. The automated mylar applicator of claim 2, wherein: the clamping driving piece is an air cylinder.

4. The automated mylar applicator of claim 2, wherein: the upper reference block comprises a product positioning column, the product positioning column extends out from the upper reference main body, and a product is sleeved on the product positioning column.

5. The automated mylar applicator of claim 2, wherein: the upper pressing block comprises an upper pressing main body and a buffer block, the upper pressing main body is provided with a product groove, and the buffer block is located in the product groove.

6. The automated mylar applicator of claim 1, wherein: the lower pressing assembly comprises a lower reference block, a lower pressing block and a pressing guide post, the pressing guide post is fixed on the lower reference block, the upper pressing assembly is sleeved on the pressing guide post and moves along the pressing guide post, and the lower pressing block is slidably mounted on the lower reference block.

7. The automated mylar applicator of claim 6, wherein: the lower reference block comprises a lower reference main body, the lower reference main body is provided with a first groove, the lower pressing block comprises a lower pressing main body, the lower pressing main body is provided with a second groove, and when the lower reference main body and the lower pressing main body are closed, the first groove and the second groove jointly form the Mylar groove.

8. The automated mylar applicator of claim 7, wherein: the lower datum body is provided with a first vertical groove, the lower pressing body is provided with a second vertical groove, and the first vertical groove and the second vertical groove form the inserting groove together when the lower datum body and the lower pressing body are folded.

9. The automated mylar applicator of claim 8, wherein: the extending direction of the inserting groove is vertical to the extending direction of the Maillard groove.

10. The automated mylar applicator of claim 7, wherein: the lower reference block further comprises a first positioning block, the first positioning block is located on the edge of the first groove, the lower pressing block further comprises a second positioning block, and the second positioning block is located on the edge of the second groove.

Technical Field

The invention relates to a Mylar film, in particular to an automatic Mylar pasting device.

Background

Mylar (PET polyester film) is a film which is prepared by heating dimethyl terephthalate and ethylene glycol with the aid of a relevant catalyst, performing ester exchange and vacuum polycondensation, and performing biaxial stretching. Has stable size, straight and excellent tear strength, heat and cold resistance, moisture and water resistance, chemical corrosion resistance, super-strong insulating property and excellent electrical, mechanical, heat and chemical resistance.

Can be used as insulating material for motor, capacitor, coil and cable, and can also be made into composite insulating material with highland barley paper. The insulating material is widely used in the electrical insulation industry, and is suitable for gaskets, baffle plates, screens and protection functions of electronics, household appliances, instruments, displays, slots of motors, computers and peripheral equipment.

The existing product is manually attached when the Mylar film is attached, so that the Mylar film attaching precision is low, the size is unstable, the yield is low, and the product quality cannot be guaranteed.

Disclosure of Invention

In order to overcome the defects of the prior art, one of the purposes of the invention is to provide an automatic mylar pasting device which is high in mylar pasting precision, stable in size, high in productivity and capable of ensuring product quality.

One of the purposes of the invention is realized by adopting the following technical scheme:

the utility model provides an automatic paste maila device, includes base, pressfitting driving piece, lower pressfitting subassembly and goes up the pressfitting subassembly, the pressfitting driving piece reaches lower pressfitting subassembly install in the base, go up the pressfitting subassembly install in the output of pressfitting driving piece, lower pressfitting subassembly is equipped with maila groove and inserting groove, maila groove with the inserting groove intercommunication, the maila pull-out piece accept in the maila groove, go up the pressfitting subassembly and include last reference block and last pressfitting piece, go up the reference block and go up the product that the pressfitting piece centre gripping was waited to paste maila, the pressfitting driving piece drives go up the pressfitting subassembly and push down until product and maila pull-out piece contact after and insert the inserting groove, make the maila pull-out piece laminate in the product surface.

Furthermore, the upper pressing block comprises a sliding block, the sliding block is provided with a sliding groove, the upper reference block comprises an upper reference main body and a clamping driving piece, the clamping driving piece is installed on the upper reference main body, the upper reference main body comprises a sliding rail, the sliding rail is contained in the sliding groove, and the clamping driving piece enables the upper reference block to slide relative to the upper pressing block.

Further, the clamping driving piece is an air cylinder.

Further, the upper reference block comprises a product positioning column, the product positioning column extends out from the upper reference main body, and the product positioning column is sleeved with a product.

Furthermore, the upper pressing block comprises an upper pressing main body and a buffer block, the upper pressing main body is provided with a product groove, and the buffer block is located in the product groove.

Furthermore, the lower pressing assembly comprises a lower reference block, a lower pressing block and a pressing guide post, the pressing guide post is fixed on the lower reference block, the upper pressing assembly is sleeved on the pressing guide post and moves along the pressing guide post, and the lower pressing block is slidably mounted on the lower reference block.

Further, the lower reference block comprises a lower reference main body, the lower reference main body is provided with a first groove, the lower pressing block comprises a lower pressing main body, the lower pressing main body is provided with a second groove, and when the lower reference main body and the lower pressing main body are closed, the first groove and the second groove jointly form the Maillard groove.

Further, the lower reference body is provided with a first vertical groove, the lower pressing body is provided with a second vertical groove, and the first vertical groove and the second vertical groove form the inserting groove together when the lower reference body and the lower pressing body are folded.

Furthermore, the extending direction of the inserting groove is perpendicular to the extending direction of the Maillard groove.

Further, the lower reference block further comprises a first positioning block, the first positioning block is located at the edge of the first groove, the lower pressing block further comprises a second positioning block, and the second positioning block is located at the edge of the second groove.

Compared with the prior art, the automatic Mylar pasting device is characterized in that the pressing driving piece and the lower pressing component of the automatic Mylar pasting device are arranged on the base, the upper pressing component is arranged at the output end of the pressing driving piece, the lower pressing component is provided with the Mylar groove and the inserting groove, the Mylar groove is communicated with the inserting groove, the Mylar is contained in the Mylar groove, the upper pressing component comprises the upper reference block and the upper pressing block, the upper reference block and the upper pressing block clamp a product to be Mylar pasted, the pressing driving piece drives the upper pressing component to press downwards until the product is in contact with the Mylar and then is inserted into the inserting groove, so that the Mylar is pasted on the surface of the product, the whole Mylar pasting process is completely mechanized and automated, the Mylar pasting precision is high, the size is stable, the productivity is.

Drawings

FIG. 1 is a perspective view of the automatic Mylar application apparatus of the present invention;

FIG. 2 is an exploded view of the self-adhesive Mylar apparatus of FIG. 1;

FIG. 3 is a perspective view of a lower press fit assembly of the self-adhesive Mylar machine of FIG. 2;

FIG. 4 is an enlarged view of the lower compression assembly A of FIG. 3;

FIG. 5 is an exploded view of the lower press fit assembly of the automated Mylar applicator of FIG. 2;

FIG. 6 is an enlarged view of the lower press assembly B of FIG. 5;

FIG. 7 is a perspective view of an upper datum block of the automated Mylar applicator of FIG. 2;

fig. 8 is a perspective view of an upper press block of the automatic mylar applicator of fig. 2.

In the figure: 10. a base; 11. a substrate; 12. supporting legs; 20. an electrical component; 30. a control button; 40. pressing the driving piece; 50. pressing the pressing component; 51. a lower reference block; 510. a lower reference body; 5101. a first groove; 5102. a first vertical groove; 511. a pickup guide post; 512. a first positioning block; 52. pressing the pressing block; 520. pressing the main body downwards; 5201. a second groove; 5202. a second vertical groove; 521. a pickup drive member; 522. a second positioning block; 523. a lower guide hole; 53. pressing the guide columns; 54. a Maillard groove; 55. inserting grooves; 60. an upper pressing component; 61. an upper reference block; 610. an upper reference body; 6101. an upper guide groove; 611. clamping the driving member; 612. a product positioning column; 613. a slide rail; 62. an upper pressing block; 620. pressing the main body upwards; 621. an upper guide block; 622. a slider; 6220. a chute; 623. a material returning driving member; 624. a buffer block; 625. and (4) a product tank.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

It will be understood that when an element is referred to as being "secured to" another element, it can be directly on the other element or intervening elements may also be present, secured by intervening elements. When a component is referred to as being "connected" to another component, it can be directly connected to the other component or intervening components may also be present. When an element is referred to as being "disposed on" another element, it can be directly disposed on the other element or intervening elements may also be present. The terms "vertical," "horizontal," "left," "right," and the like as used herein are for illustrative purposes only.

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

Referring to fig. 1 to 8, an automatic mylar pasting device according to the present invention includes a base 10, an electrical component 20, a control button 30, a pressing driving component 40, a lower pressing component 50, and an upper pressing component 60.

The base 10 includes a substrate 11 and supporting legs 12. The supporting legs 12 are fixed to the bottom surface of the substrate 11. The support feet 12 are cylindrical. The number of the supporting feet 12 is four. The substrate 11 is rectangular, and the supporting legs 12 are fixed to four corners of the substrate 11.

The electric component 20 and the control button 30 are fixed to the substrate 11. The control button 30 is electrically connected to the electrical component 20. The pressing driving member 40 is fixed to the substrate 11. The press driving member 40 is a cylinder. The pressing driving member 40 is electrically connected to the electrical component 20.

The lower press assembly 50 includes a lower reference block 51, a lower press block 52, and a press guide 53. The lower reference block 51 is fixedly attached to the base plate 11 of the base 10. The stitching guide 53 is fixed to the lower reference block 51 and is perpendicular to the lower reference block 51. The lower reference block 51 includes a lower reference body 510, two pick-off guide posts 511, and a plurality of first positioning blocks 512. Two pick-off guide posts 511 extend from the lower reference body 510. The lower reference body 510 is provided with a first groove 5101 and a first vertical groove 5102. A plurality of first positioning blocks 512 are located at the edge of the first groove 5101. The first groove 5101 extends to the edge of the lower reference body 510. The first vertical trough 5102 is located at an edge of the lower reference body 510. The extending direction of the first groove 5101 is perpendicular to the extending direction of the first vertical groove 5102. The lower press-fit block 52 includes a lower press-fit body 520, a pickup actuator 521, and a second positioning block 522. The pickup driving member 521 is electrically connected to the electrical component 20. The lower press-fit block 52 is also provided with a lower guide hole 523. The lower press-fit body 520 is provided with a second groove 5201 and a second vertical groove 5202. The second recess 5201 extends to the edge of the lower press main body 520. The second vertical slot 5202 is located at the edge of the lower press body 520. The extending direction of the second vertical groove 5202 is perpendicular to the extending direction of the second recess 5201. The pickup actuator 521 is fixed to the lower press body 520. The pickup driving member 521 is a cylinder. The second positioning block 522 is located at the edge of the second recess 5201.

The upper press assembly 60 includes an upper reference block 61 and an upper press block 62. The upper reference block 61 includes an upper reference body 610, a clamping driving member 611, a product positioning post 612, and a slide rail 613. The upper reference body 610 is provided with an upper guide groove 6101. The clamp drive 611 is fixedly mounted to the upper datum body 610. The product positioning post 612 and the sliding rail 613 extend from the upper reference body 610. The clamp drive 611 is a pneumatic cylinder. The clamping driving member 611 is electrically connected to the electrical component 20. The upper pressing block 62 includes an upper pressing body 620, an upper guide block 621, a slider 622, a material returning driving member 623, and a buffer block 624. The upper stitching block 62 is also provided with a product channel 625. The upper guide block 621 and the slider 622 are fixed to the upper press main body 620. The slider 622 is provided with a sliding slot 6220. The material returning driving member 623 is mounted on the upper pressing body 620. A buffer block 624 is located in the product tank 625.

When the automatic mylar sticking device is in an initial state, the lower reference block 51 and the lower pressing block 52 are folded, and the first groove 5101 and the second groove 5201 form a mylar groove 54 together. The first vertical slot 5102 and the second vertical slot 5202 together form the insertion slot 55. The insertion groove 55 extends vertically downward. The extension direction of the mylar grooves 54 is parallel to the horizontal plane. The mylar grooves 54 communicate with the mating grooves 55.

The mylar sheet is placed in the mylar groove 54 and is positioned by the first positioning block 512 and the second positioning block 522. The mylar grooves 54 are connected to a vacuum generator so that the mylar sheets are positioned in the mylar grooves 54 by drawing a vacuum. The product to be adhered with the mylar sheet is positioned on the upper reference block 61 through the product positioning column 612, the clamping driving piece 611 pushes the upper reference main body 610 to be close to the upper pressing block 62, so that the product is accommodated in the product groove 625, and at the moment, the product is clamped between the upper reference block 61 and the upper pressing block 62.

The electrical component 20 controls the upper pressing component 60 to drive the product to move down along the pressing guide column 53, the product contacts with the mylar sheet on the lower pressing component 50 until the mylar sheet is inserted into the insertion groove 55, and at this time, the mylar sheet is attached to the surface of the product. The electrical component 20 controls the pick-up driving member 521 to drive the lower pressing block 52 to move backward, and the material returning driving member 623 drives the upper pressing body 620 to move upward. The product stuck with the mylar can be taken out conveniently.

The whole mylar pasting process is completely mechanized and automated, the mylar pasting precision is high, the size is stable, the productivity is high, and the product quality can be guaranteed.

The above examples only show some embodiments of the present invention, and the description thereof is more specific and detailed, but not construed as limiting the scope of the invention. It should be noted that, for those skilled in the art, variations and modifications can be made without departing from the spirit of the invention, and all equivalent modifications and changes can be made to the above embodiments according to the essential technology of the invention, which falls into the protection scope of the invention.