TWI577557B - Vacuum patch - Google Patents

Description

Vacuum patch

The present invention relates to a patch that is vacuum attached to a flat surface, and more particularly to a vacuum patch that can be separated into a plane in a specific direction.

The patch is a strip-shaped adhesive article, and with the evolution of technology, the patch can not only adhere to the surface of some items, as a connection between two different items, or some kind of shielding and protection. It is more widely used in various fields of food and clothing.

At present, the electronic industry production line uses high-temperature resistant tape to adhere to the fixed workpiece for process production. After the production is completed, the high-temperature resistant tape must be removed from the workpiece, and the high-temperature resistant tape can not be used twice after the process, so it costs more. High human resources carry out subsequent related processing operations on the high temperature resistant tape, which will also increase the manufacturing cost, and the high temperature resistant tape is more difficult to be peeled off from the surface of the workpiece because the high temperature resistant tape is adhered to the surface of the workpiece. Excessive or incorrect force to tear off the high temperature tape will cause some of the high temperature resistant tape to remain on the surface of the workpiece, which in turn requires extra time for the tearing operation.

However, in general applications of the people's livelihood, after a period of use of the adhesive tape, the adhesiveness will gradually lose the adhesive effect due to the influence of time and environmental factors. Therefore, it is generally necessary to pay attention to whether the adhesiveness of the adhesive tape is still certain. Standard, and replace the tape before it loses its viscosity. However, during the process of changing the tape, the adhesive layer on the tape may remain on the flat surface, which will take extra time to leave the remaining adhesive. The layer is cleaned up.

In view of this, there are still some shortcomings in the use, and there is a need to improve and innovate the conventional tape so that the tape can be peeled off from the plane.

The main purpose of the present invention is to remove the vacuum patch from the plane in a specific direction when the vacuum patch is attached to the plane, thereby achieving the purpose of rapid tearing and labor saving.

The secondary object of the present invention is to prevent dust in the air from adhering to the surface of the vacuum patch, thereby continuously maintaining the surface of the vacuum patch so that the adhesion force of the vacuum patch attached to the plane can be effectively prevented. weak.

To achieve the above object, the vacuum patch of the present invention can be used to vacuum attach an object to a flat surface, wherein the vacuum patch is mainly composed of a vacuum adsorption layer, a deformation layer, an adhesive layer and a protective layer. The vacuum adsorption layer respectively forms a first surface and a second surface on opposite sides, and the first surface of the vacuum adsorption layer can be repeatedly adsorbed or separated from one of the object and the plane, and the second surface has a first area and a second area surrounding the first area.

The deformation layer is coupled to the second surface and has a first portion located in the first region and at least a second portion extending from the first portion toward the second region, wherein the volume of the second portion is less than the above a part of the volume, wherein the adhesive layer is located on one side of the deformation layer and adheres to the other of the object and the plane, and the protective layer is provided with a joint between the deformation layer and the adhesive layer. And a covering portion protruding from the vacuum adsorption layer, wherein the connecting portion and the covering portion have a bent portion, and the covering portion is transmitted through the bent portion to be covered by the first surface The cleaving position is folded over to a covering position covering the first surface.

The second portion extends to a periphery of the second region, and the second portion is turned over the vacuum adsorption layer toward the first portion, and the first surface is separated from the plane.

In a preferred embodiment, a difference between the end of the second portion and the edge of the second region is formed, and the length of the phase difference affects the strength of the vacuum absorbing layer of the second portion. . In another preferred embodiment, the second portion extends from the first portion to the periphery of the second region.

In the above two preferred embodiments, the portion of the second surface of the second surface that is not covered by the deformation layer forms a spacer region at the periphery of the deformation layer, and the spacer region is provided with a thickness smaller than the deformation of the deformation layer. And a layer connected to the vacuum adsorption layer and the adhesion layer and forming a separation distance from the other.

Further, the vacuum adsorption layer comprises: a heat-resistant portion, a first dielectric surface, a second dielectric surface, a third dielectric surface, an adhesive portion, and a connecting portion, wherein the heat-resistant portion is formed on each of the opposite sides a first side surface and a second side surface; the first dielectric surface is located on the first side surface of the heat-resistant portion; the second dielectric surface is located above the first dielectric surface; the third dielectric surface is located on the second side of the heat-resistant portion; The adhesive portion is heat-pressed on the second dielectric surface and adhered to the plane; the connecting portion is located on the third dielectric surface side and is connected to the deformation layer.

Wherein, the heat-resistant portion comprises a fiberglass cloth and an epoxy resin, and the adhesive portion comprises a silicone rubber, a hardener, a colorant, and an adhesive, and the pressure-resistant layer is located at a peripheral edge of the vacuum adsorption layer, such that the pressure-sensitive layer and the pressure-sensitive layer The deformation layer together forms a contour identical to the contour of the vacuum adsorption layer described above.

The invention is characterized in that when the deformation layer is connected to the second surface of the vacuum adsorption layer, the second portion of the deformation layer is located at the edge of the second region, whereby the second portion can be turned over by the vacuum adsorption layer toward the first portion. The force is concentrated in the second portion, and the second portion separates the local extent of the first surface from the object or plane to allow air to flow between the plane and the object and the first surface plane, enabling rapid It also labor-savingly separates the vacuum patch from the plane.

In addition, when the covering portion of the protective layer is folded to the covering position through the bending portion, the covering portion covers the first surface of the vacuum adsorption layer to prevent dust in the air from adhering to the first surface, thereby maintaining the first The surface is clean, so that the adhesion strength of the first surface to the object or the plane is effectively prevented from becoming weak.

In order to further clarify and understand the structure, the use and the features of the present invention, the preferred embodiment is described in detail with reference to the following drawings:

Referring to FIG. 1 and FIG. 2, the vacuum patch 1 of the present invention is mainly composed of a vacuum adsorption layer 10, a deformation layer 20, an adhesive layer 30, and a pressing layer 40. The vacuum adsorption layer 10 defines a first surface 101 and a second surface 102 on the upper and lower sides. The second surface 102 forms a first region 102a in the central region, and forms a first portion on the periphery of the first region 102a. The second region 102b, wherein the vacuum adsorption layer 10 includes a heat-resistant portion 11, a first dielectric surface portion 12, a second dielectric surface portion 13, a third dielectric surface portion 14, and an adhesive portion 15 as shown in FIG. And a connecting portion 16, the heat-resistant portion 11 has a first side surface 111 and a second side surface 112 formed on an opposite side of the first side surface 111, wherein the heat-resistant portion 11 is made of a flexible material, so that the heat resistance is The portion 11 can be bent. In the preferred embodiment, the heat-resistant portion 11 is made of a fiberglass cloth and an epoxy resin.

As shown in the figure, the first dielectric surface portion 12 and the second dielectric surface portion 13 are sequentially located above the first side surface 111 of the heat-resistant portion 11 such that the first dielectric surface portion 12 is located between the heat-resistant portion 11 and the second dielectric surface portion 13. The third dielectric surface portion 14 is connected to the second side surface 112 of the heat-resistant portion 11, and the adhesive portion 15 has the first surface 101 and is heat-pressed to the second dielectric surface portion 13, and the connecting portion 16 The second surface 102 is connected to the third dielectric surface portion 14, whereby the adhesive portion 15 and the connecting portion 16 are respectively located on opposite sides of the vacuum adsorption layer 10. In the preferred embodiment, the adhesive portion 15 is made of silicone, a hardener, a colorant, and an adhesive.

Referring to FIG. 1 and FIG. 2, the deformation layer 20 has a shape smaller than the vacuum adsorption layer 10, and has a first portion 21 and a second portion 22 formed by the first portion 21 extending in a first direction A. The volume of the second portion 22 is smaller than the volume of the first portion 21, and as shown, since the shape of the deformation layer 20 is smaller than the vacuum adsorption layer 10, the deformation layer 20 is connected to the portion of the second surface 102. a portion, such that a portion of the second surface 102b of the second surface 102 that is not covered by the deformation layer 20 forms a spacer region 102c located at a periphery of the deformation layer 20, wherein the first portion 21 of the deformation layer 20 is located at the second portion The first region 102a of the surface 102 is such that the first portion 21 is located in a central region of the second surface 102, and the second portion 22 is located in a partial extent of the second region 102b such that the periphery of the second portion 22 is aligned The periphery of the vacuum adsorption layer 10 described above. In a preferred embodiment, the deformation layer 20 is provided as an elastic glue.

The adhesive layer 30 has a shape equal to the vacuum adsorption layer 10 and is connected to the deformation layer 20 such that the deformation layer 20 is located between the vacuum adsorption layer 10 and the adhesive layer 30, wherein the adhesive layer 30 is connected to the above When the layer 20 is deformed, the outer peripheral side of the adhesive layer 30 is aligned with the outer peripheral side of the vacuum adsorbing layer 10. However, the outer surface of the adhesive layer 30 may be provided with a pattern to increase the double-sided adhesive pointing vacuum sticker. The appearance of the sheet 1 is such that the appearance of the pressing layer 40 is approximately U-shaped and is located in the spacing portion 102c. When the pressing layer 40 is located in the spacing portion 102c, the pressing layer 40 is located in the vacuum adsorption. The peripheral position of the layer 10 is such that the contours of the pressure-sensitive layer 40 and the deformation layer 20 are formed to have the same contour as the vacuum adsorption layer 10 described above.

As shown in the figure, the thickness of the pressing layer 40 is smaller than the thickness of the adhesive layer 30, and the upper surface of the pressing layer 40 is connected to the adhesive layer 30, and the lower surface of the pressing layer 40 and the vacuum adsorption A spacing distance 50 is formed between the second surfaces 102 of the layer 10. However, the upper surface of the pressing layer 40 is connected to the adhesive layer 30, that is, the lower surface of the pressing layer 40 is connected to the vacuum. The second surface 102 of the adsorption layer 10 is formed between the adhesive layer 30 and the upper surface of the pressure-sensitive adhesive layer 40. In the preferred embodiment, the pressure-sensitive adhesive layer 40 is formed as an elastic rubber. As shown in the figure, the vacuum patch 1 has a circular appearance. However, the vacuum patch 1 has a circular shape for convenience of description, that is, the vacuum patch 1 can be square, trapezoidal, elliptical or triangular. Or other special shapes.

Referring to FIG. 4 and FIG. 5, in a specific application, the adhesive layer 30 is adhered to the surface of an object 60, so that the adhesive layer 30 is located between the deformation layer 20 and the object 60, as shown in the figure. 60 is set as a mobile electronic device (such as a mobile phone, a tablet computer, a mobile power source), and then the first surface 101 of the vacuum adsorption layer 10 faces a plane 70, and the vacuum patch 1 faces the above through the object 60. The plane 70 applies a pressure such that the separation distance 50 between the pressing layer 40 and the vacuum adsorption layer 10 becomes smaller and smaller, so that the pressing layer 40 touches the vacuum adsorption layer 10, so that the first surface 101 is The partial region is vacuum-attached to the plane 70 by the pressing of the pressing layer 40, and the portion of the first surface 101 not attached to the plane 70 is pushed by the deformation layer 20 and vacuum-attached to The plane 70 described above, wherein the plane 70 can be set to a smooth plane.

The adhesive portion 15 is adhered to the heat-resistant portion 11 via the first dielectric surface portion 12 and the second dielectric surface portion 13, and is adhered to the heat-resistant portion 11 by high-temperature and high-pressure treatment to make the vacuum. When the adhesive portion 15 of the adsorption layer 10 is adhered to the flat surface 70, the effect of vacuum adsorption can be automatically generated, and the object 60 can be connected to the flat surface 70 through the vacuum adsorption layer 10, thereby causing the first surface 101 and the flat surface 70. There is no air between them, making it difficult for the object 60 to be separated from the plane 70 described above.

Referring to FIG. 6, when the object 60 is to be separated from the plane 70, the object 60 is held, and the second portion 22 of the deformation layer 20 faces a second direction B opposite to the first direction A. In order to turn over the vacuum adsorption layer 10, since the second portion 22 of the deformation layer 20 is located at the edge of the second region 102b of the second surface 102, the force is concentrated on the second portion 22 of the deformation layer 20, thereby The second portion 22 can separate the partial range of the first surface 101 from the plane 70 to allow air to flow between the first surface 101 and the plane 70, whereby air flows into the first surface 101 and the plane. Between 70, the vacuum patch 1 described above can be quickly and laboriously separated from the plane 70 described above. On the other hand, since the object 60 is hardly separated from the plane 70 by the vacuum attachment of the vacuum patch 1 to the plane 70, the vacuum adsorption layer 10 is not turned by the second portion 22 in the second direction B. This causes a dispersion of force which makes it difficult to separate the vacuum patch 1 described above from the plane 70 described above.

However, the adhesive layer 30 is adhered to the object 60, and the vacuum adsorption layer 10 is vacuum-adsorbed to the flat surface 70. The adhesive layer 30 is not limited to be adhered to the object 60, and the adhesive layer 30 is not limited. The vacuum adsorption layer 10 vacuum-adsorbs the flat surface 70. As shown in FIG. 7, the adhesive layer 30 is first adhered to the flat surface 70 such that the vacuum adsorption layer 10 faces the object 60, and then the object 60 faces the vacuum. The adsorption layer 10 applies pressure to cause the above-mentioned object 60 and the vacuum adsorption layer 10 to be attached to each other.

Referring to FIG. 8 , in the second preferred embodiment, the vacuum patch 1 is further provided with a protective layer 80 such that the vacuum patch 1 is covered by the vacuum adsorption layer 10 , the deformation layer 20 , and the adhesive layer 30 . The structure of the vacuum layer 40, the deformation layer 20, the adhesive layer 30, and the pressing layer 40 is the same as that of the first preferred embodiment, and will not be described herein. Only the assembly position and structure of the above protective layer 80 are further described.

As shown in the figure, the protective layer 80 has a bent portion 81. The opposite sides of the bent portion 81 respectively form a plurality of connecting portions 82 and a covering portion 83. The connecting portion 82 covers the deformed layer 20 and Above the pressing layer 40, the connecting portion 82 is located between the deformation layer 20 and the adhesive layer 30, and the covering portion 83 is convexly protruded from the vacuum adsorption layer 10.

Referring to FIG. 9 , the covering portion 83 of the protective layer 80 can be turned over by a covering position 831 not covering the first surface 101 to a covering position 832 covering the first surface 101 . When the covering portion 83 is located at the covering position 832, the covering portion 83 can prevent dust in the air from adhering to the first surface 101, thereby keeping the first surface 101 clean, so that the first surface 101 can be effectively prevented. The attachment force attached to the plane 70 is weakened, and the manner of use is the same as that of the first preferred embodiment, and will not be described herein.

Referring to FIG. 10, in the third preferred embodiment, the difference from the first preferred embodiment is the shape of the deformation layer 20 and the number of the pressing layers 40, as compared with the first preferred embodiment. The same portions will not be described again. As shown, the deformation layer 20 has a first portion 21 and five second portions 22 formed by the first portion 21 extending toward the second region 102b with the first portion 21. The appearance of the deformation layer 20 is star-shaped, whereby the portion of the second region 102b not covered by the deformation layer 20 forms five spacer regions 102c having the same shape. In this embodiment, the vacuum patch 1 is There are five pressing layers 40 having shapes corresponding to the above-mentioned spacer regions 102c, and the above-mentioned five pressing layers 40 are respectively located one to one in the above-described five spaced regions 102c.

Referring to FIG. 11, in the fourth preferred embodiment, the difference from the first preferred embodiment lies in the deformation layer 20. As shown, the first portion 21 and the second portion 22 are respectively connected to the first portion. The region 102a and the second region 102b form a phase difference 90 between the end of the second portion 22 and the periphery of the second region 102b, and the length of the phase difference 90 will affect the second portion 22 The magnitude of the force of the vacuum adsorption layer 10, in other words, the longer the length of the phase difference 90, causes the second portion 22 to separate the first surface 101 from the plane 70 with a large turning force, and vice versa. The shorter the length of the phase difference 90 is, the second portion 22 is separated from the plane 70 by a small turning force, whereby the second portion 22 is located at the above In the second region 102b, the vacuum adsorption layer 10 is turned over in the second direction B, and the first surface 101 is separated from the plane 70.

The above embodiments are intended to be illustrative only, and are not intended to limit the scope of the present invention. It is included in the scope of the following patent application.

1‧‧‧vacuum patch
10‧‧‧vacuum adsorption layer
101‧‧‧ first surface
102‧‧‧ second surface
102a‧‧‧First area
102b‧‧‧Second area
102c‧‧‧Interval area
11‧‧‧Heat Department
111‧‧‧ first side
112‧‧‧ second side
12‧‧‧First face
13‧‧‧Second facial
14‧‧‧ third face
15‧‧‧Adhesive Department
16‧‧‧Connecting Department
20‧‧‧ deformation layer
21‧‧‧Part 1
22‧‧‧Part II
30‧‧‧Adhesive layer
40‧‧‧Resist layer
50‧‧‧ separation distance
60‧‧‧ objects
70‧‧‧ plane
80‧‧ ‧ protective layer
81‧‧‧Bending
82‧‧‧Team
83‧‧‧ Coverage
831‧‧‧Open position
832‧‧‧ Cover position
90‧‧‧distance distance
A‧‧‧First direction
B‧‧‧second direction

1 is an exploded view of a vacuum preferred embodiment of the present invention; FIG. 2 is a cross-sectional view of FIG. 1; FIG. 3 is an exploded view of the vacuum adsorption layer; Figure 5 is a schematic view showing the use of the vacuum patch attached to the plane of the vacuum patch of the present invention; Figure 6 is a schematic view showing the use of the vacuum patch of the present invention separated from the plane; Figure 7 is a schematic view showing the use of the article of the present invention adhered to the pointing vacuum patch 8 is an exploded view of the second preferred embodiment of the vacuum patch of the present invention; FIG. 9 is a schematic view showing the movement of the covering portion of the protective layer between the split position and the covering position; FIG. 10 is a third preferred embodiment of the vacuum patch of the present invention. An exploded view of the embodiment; and Figure 11 is a schematic view of a fourth preferred embodiment of the vacuum patch of the present invention.

1‧‧‧vacuum patch

10‧‧‧vacuum adsorption layer

101‧‧‧ first surface

102‧‧‧ second surface

102a‧‧‧First area

102b‧‧‧Second area

102c‧‧‧Interval area

20‧‧‧ deformation layer

21‧‧‧Part 1

22‧‧‧Part II

30‧‧‧Adhesive layer

40‧‧‧Resist layer

A‧‧‧First direction

Claims (10)

A vacuum patch for attaching an object to a plane, comprising: a vacuum adsorption layer having a first surface capable of repeatedly adsorbing or separating from one of the object and the plane; and a first surface a second surface on the opposite side of the surface, the second surface has a first region and a second region surrounding the first region; an adhesive layer spaced apart from the second surface of the vacuum adsorption layer for bonding The other of the object and the plane; and a deformation layer coupled to the second surface and having a first portion located in the first region and at least one extending from the first portion toward the second region a second portion, wherein the portion of the second surface not covered by the deformation layer forms at least one spacer region located at an outer periphery of the deformation layer; wherein the second portion is capable of flipping the vacuum adsorption layer toward the first portion, thereby The first surface is separated from the plane. The vacuum patch according to claim 1, wherein the vacuum patch further has a protective layer, and the protective layer has a covering portion disposed on the first surface. The vacuum patch of claim 2, wherein the protective layer further has a joint portion between the deformation layer and the adhesive layer, and a bend between the joint portion and the cover portion The portions are connected to each other such that the covering portion passes through the bent portion and can be folded from a split position not covering the first surface to a covering position covering the first surface. The vacuum patch according to claim 1, wherein the spacer region is provided with a pressing layer having a thickness smaller than the deformation layer, and the pressing layer is connected to one of the vacuum adsorption layer and the adhesive layer, and A separation distance is formed with the other. The vacuum patch according to claim 4, wherein the pressing layer is located at a peripheral position of the vacuum adsorption layer such that the pressing layer and the deformation layer together form a contour identical to the contour of the vacuum adsorption layer. . The vacuum patch of claim 1, wherein an end of the second portion forms a phase difference with an edge of the second region, and the length of the phase difference affects the second portion of the translation. The strength of the above vacuum adsorption layer. The vacuum patch according to claim 1, wherein the second portion extends from the first portion to a periphery of the second region such that the second portion can directly flip the edge of the vacuum adsorption layer. The vacuum adhesive sheet according to the first aspect of the invention, wherein the vacuum adsorption layer comprises: a heat-resistant portion, respectively forming a first side surface and a second side surface on opposite sides; a first dielectric surface located at the heat resistance a first side surface; a second dielectric surface located above the first dielectric surface; a third dielectric surface located on the second side of the heat-resistant portion; an adhesive portion pressed against the second dielectric surface and attached And affixed to one of the object and the plane; and a connecting portion on a side of the third dielectric surface and connected to the deformation layer. The vacuum patch according to claim 8, wherein the heat-resistant portion comprises a fiberglass cloth and an epoxy resin. The vacuum patch according to claim 8, wherein the adhesive portion comprises silicone, a hardener, a colorant, and an adhesive.