CN118055607A - Conductive gasket, detection method and detection system - Google Patents

Abstract

The invention discloses a conductive gasket, a detection method and a detection system, and relates to the technical field of conductive gaskets, wherein a gasket block is adhered to a movable film through a back adhesive layer, and the movable film can be repeatedly adhered to a groove on a double-layer release film. The detection method of the conductive gasket comprises the following steps: the movable film is stripped from the groove and then conveyed to a detection station; then detecting the pad block on the movable film; and finally, moving the movable film out of the detection station and bonding the movable film in the groove again. The pad block is provided with the area for conducting current with the detection platform during detection, and the back adhesive layer on the pad block is adhered to the movable film for detection, so that the back adhesive layer is prevented from being adhered to the detection platform during detection, the automatic detection of the performances of all products is realized on the premise of not damaging the back adhesive layer of the products, the detection efficiency is improved, and each product discharged is ensured to meet the performance requirement.

Description

Conductive gasket, detection method and detection system

Technical Field

The invention relates to the technical field of conductive gaskets, in particular to a conductive gasket, a detection method and a detection system.

Background

Conductive pads are commonly used to fill gaps inside electronic devices to reduce leakage of electromagnetic waves. In the production process of the conductive pad, the compression resistance and compression rebound stress of the conductive pad need to be detected.

The conductive pad in the prior art is usually provided with a back adhesive layer, and when the conductive pad is tested for compression resistance and compression rebound stress, the conductive pad needs to be taken out from the carrier film and attached to a test platform for compression test. However, after the test is completed, the back adhesive layer of the conductive pad is adhered and fixed with the test platform, which belongs to a destructive detection mode, so that only spot inspection can be performed, full inspection cannot be performed, and the yield cannot be ensured. And after the test is finished, the sample is required to be forcibly removed from the test platform by hand, so that the test efficiency is low.

Accordingly, the prior art is subject to improvement and development.

Disclosure of Invention

Aiming at the defects in the prior art, the invention aims to provide a conductive gasket, a detection method and a detection system, which are used for solving the technical problems that the conventional conductive gasket cannot be subjected to full detection and has low detection efficiency.

The technical scheme adopted by the invention for solving the problems is as follows:

a conductive pad, comprising: the bottom surface of the pad block comprises a first area and a second area, and the second area is used for conducting current with the detection platform during detection;

the back adhesive layer is arranged in the first area;

the double-layer release film is provided with a groove;

The movable film is arranged in the groove and can be repeatedly bonded with the bottom surface of the groove;

The pad piece is adhered to the movable film through the gum layer, and the release force between the gum layer and the movable film is smaller than that between the gum layer and the bottom surface of the groove.

Optionally, the movable film is strip-shaped, and the long side of the movable film is parallel to the long side of the double-layer release film.

Optionally, the central area of the bottom surface of the spacer block is the first area, the edge area of the bottom surface of the spacer block is the second area, the side parallel to the short side of the movable film on the gum layer is the first side, the side parallel to the short side of the movable film on the spacer block is the second side, the width of the movable film is greater than the side length of the first side, and the width of the movable film is less than the side length of the second side.

Optionally, the backing block and the backing layer are bonded to form a pad body, and the pad body is provided in plurality and is provided at intervals along the long side of the movable film.

Optionally, the double-layer is from type membrane including first from type membrane and second from type membrane, first from type membrane bond in on the second is from type membrane, be equipped with the fretwork area on the first from type membrane, fretwork area with the second is from type membrane to enclose into the recess.

A method of detecting a conductive pad as claimed in any one of the preceding claims, comprising the steps of:

Peeling the movable film attached with the lining pad from the groove;

conveying the movable film attached with the lining pad to a detection station;

Detecting the pad block attached to the movable film;

and moving the movable film attached with the lining pad out of the detection station and bonding the movable film in the groove again.

Optionally, the step of conveying the movable film attached with the lining pad to a detection station specifically includes:

The movable film is pulled to enter a detection station from the feeding side of the detection platform through the upper surface of the detection platform;

And the double-layer release film is pulled to be conveyed to the blanking side of the detection platform from the feeding side of the detection platform through the lower surface of the detection platform.

Optionally, the step of detecting the pad block attached to the movable film specifically includes:

Compressing the pad block;

detecting a compression resistance value of the pad block;

And detecting the compression rebound stress of the gasket block.

Optionally, after the movable film attached with the spacer block moves out of the detection station and is adhered in the groove, the method further comprises:

and rolling the conductive gasket after detection.

A detection system for a conductive pad for performing the detection method as claimed in any one of the above, and detecting a conductive pad as claimed in any one of the above, the detection system comprising:

The pressing detection module is used for compressing and detecting the gasket block;

the detection platform is arranged right below the downward-pressing detection module and is used for supporting the lining pad;

And the conveying and winding module is arranged on the discharging side of the detection platform and used for conveying the conductive gasket to the detection platform and winding the detected conductive gasket.

In summary, the beneficial effects of the invention are as follows:

According to the invention, the back adhesive layer is adhered to the movable film for detection, so that the back adhesive layer is prevented from being adhered to the detection platform in the detection process, the detected conductive liner can be easily taken out, the performance of all products can be automatically checked on the premise of not damaging the back adhesive layer of the products, the detection efficiency is improved, and each product of the shipment can meet the performance requirement.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the following description will briefly explain the embodiments or the drawings needed in the prior art, and it is obvious that the drawings in the following description are only some embodiments described in the present invention, and other drawings can be obtained according to the drawings without inventive effort for a person skilled in the art.

FIG. 1 is a schematic diagram of a conductive pad according to the present invention;

FIG. 2 is a partial cross-sectional view of a conductive pad of the present invention;

FIG. 3 is a flow chart of a method for inspecting a conductive pad according to the present invention;

FIG. 4 is a schematic diagram of the structure of the movable membrane and the double-layer release film according to the present invention;

FIG. 5 is a diagram showing the structural relationship between the conductive pad and the detection system according to the present invention.

Wherein: 100. a spacer block; 200. a back adhesive layer; 300. a double-layer release film; 310. a first release film; 320. a second release film; 400. a movable membrane; 500. a pressing detection module; 510. a detection head; 600. a detection platform; 700. and conveying the winding module.

Detailed Description

In order to enable those skilled in the art to better understand the present invention, a technical solution in the embodiments of the present invention will be clearly and completely described below with reference to the accompanying drawings in the embodiments of the present invention, and it is apparent that the described embodiments are only some embodiments of the present invention, not all embodiments. Based on the embodiments of the present invention, other embodiments that may be obtained by those of ordinary skill in the art without making any inventive effort are within the scope of the present invention.

Referring to fig. 1 and 2, in an embodiment of the present invention, a conductive pad is disclosed, including a pad block 100, wherein a bottom surface of the pad block 100 includes a first area and a second area, and the second area is used for conducting current with a detection platform 600 during detection; a backing adhesive layer 200 disposed in the first region; a double-layer release film 300, wherein a groove is arranged on the double-layer release film 300; the movable film 400 is arranged in the groove and can be repeatedly bonded with the bottom surface of the groove; the pad block 100 is adhered to the movable film 400 through the adhesive-backed layer 200, and the release force between the adhesive-backed layer 200 and the movable film 400 is smaller than the release force between the adhesive-backed layer 200 and the bottom surface of the groove.

The double-layer release film 300 comprises a first release film 310 and a second release film 320, the first release film 310 is adhered to the second release film 320, a hollowed-out area is formed in the first release film 310, and the hollowed-out area and the second release film 320 enclose the groove. The first release film 310 may be in the same size as the second release film 320, the first release film 310 and the second release film 320 may be attached by an attaching machine, after the attaching, the first release film 310 is cut by a circular knife process or other die cutting process, the cut area is the movable film 400, and the movable film 400 may move in a vertical direction and a horizontal direction relative to the second release film 320. In the non-detection state, the second release film 320 is used for attaching and fixing the movable film 400, so as to avoid deformation of the movable film 400.

In this embodiment, the release force between the backing layer 200 and the movable film 400 is smaller than the release force between the backing layer 200 and the bottom surface of the groove, and the release force refers to the release force between the release film and the adherend, and is generally expressed in gf/in or N/10 mm. The greater the release force, the greater the force required to peel, whereas the smaller the release force, the less the force required to peel. The release force of the first release film 310 may be selected to be 20 to 50gf/in, and the release force of the second release film 320 may be selected to be 200 to 400gf/in. In this embodiment, the release force between the movable film 400 and the backing film 200 is smaller than the release force between the movable film 400 and the second release film 320, so as to prevent the movable film 400 and the second release film 320 from being separated by the tensile force generated when the backing film 200 on the spacer block 100 is separated from the movable film 400, and the use is convenient.

Specifically, in a normal state, the pad block 100 is adhered to the movable film 400 through the backing layer 200, when detection is required, the movable film 400 adhered with the pad block 100 is separated from the second release film 320 and placed on the detection platform 600 for detection, after detection is completed, the movable film 400 is reset again and is adhered in the groove on the double-layer release film 300, and because the second area on the pad block 100 is located outside the coverage area of the movable film 400, the part of the movable film 400 beyond the backing layer 200 does not completely shield the conductive layer on the pad block 100, so that the conductive layer on the second area of the pad block 100 can be conducted with the detection platform 600 after the pad block 100 is compressed, and the effect of protecting the backing layer 200 on the pad block 100 is realized while the conductive layer on the pad block 100 can normally conduct current in the detection process is ensured.

In this embodiment, the movable film 400 is elongated, and the long side of the movable film 400 is parallel to the long side of the double-layer release film 300.

In this embodiment, the pad block 100 and the backing layer 200 are adhered to form a pad body, and a plurality of pad bodies are provided at intervals along the long side of the movable film 400.

Specifically, when detection is required, the plurality of spacer blocks 100 on the movable film 400 are simultaneously placed on the detection platform 600 for detection, and after detection is completed, the plurality of spacer blocks 100 can be simultaneously moved out of the detection platform by only moving the double-layer release film 300, so that the plurality of spacer blocks 100 can be detected once, and the detection efficiency is improved.

Referring to fig. 2, in the present embodiment, the central area of the bottom surface of the pad block 100 is the first area, the edge area of the bottom surface of the pad block 100 is the second area, the side parallel to the short side of the movable film 400 on the backing adhesive layer 200 is the first side, the side parallel to the short side of the movable film 400 on the pad block 100 is the second side, the width of the movable film 400 is greater than the side length of the first side, and the width of the movable film 400 is less than the side length of the second side.

For example, the width of the movable film 400 may be 3mm greater than the first edge on the adhesive-backed layer 200, so that the pad 100 and the movable film 400 are aligned, and meanwhile, the movable film 400 is guaranteed to be capable of completely carrying the adhesive-backed layer 200, so that the adhesive-backed layer 200 is prevented from being adhered to the detection platform 600 in the detection process, and the integrity of the adhesive-backed layer 200 cannot be guaranteed. The width of the movable film 400 is smaller than the length of the second side of the pad block 100, so that the movable film 400 is prevented from completely shielding the conductive layer of the second area, and the current conduction is prevented, so that the test result of the compression resistor is far greater than the actual value.

In this embodiment, the pad block 100 may have a rectangular shape, and the short side of the pad block 100 is disposed parallel to the long side of the movable film 400.

Specifically, the long side of the pad block 100 is the second side, that is, the long side of the pad block 100 is parallel to the width direction of the movable film 400, and the short side of the pad block 100 is parallel to the long side of the movable film 400, so that more pad blocks 100 can be arranged on the movable block with a certain length, and the detection efficiency is improved.

As another embodiment of the present application, there is also disclosed a detection method for the conductive pad as described in any one of the above, comprising the steps of:

S100, peeling the movable film attached with the lining block from the groove.

And S200, conveying the movable film attached with the lining pad to a detection station.

And S300, detecting the pad block attached to the movable film.

S400, moving the movable film attached with the lining pad out of the detection station and bonding the movable film in the groove again.

In a specific embodiment, the step of conveying the movable film attached with the backing block to a detection station specifically includes:

s210, pulling the movable film to enter a detection station from the feeding side of the detection platform through the upper surface of the detection platform.

S220, dragging the double-layer release film to be conveyed to the blanking side of the detection platform from the feeding side of the detection platform through the lower surface of the detection platform.

Specifically, referring to fig. 3 and 4, the double-layer release film 300 is pulled, so that the double-layer release film 300, the movable film 400 adhered to the double-layer release film 300, and the pad block 100 adhered to the movable film 400 simultaneously move toward the direction of the detection platform 600, when the movable film 400 and the double-layer release film 300 approach the detection platform 600, the movable film 400 is peeled from the double-layer release film 300, so that the movable film 400 adhered with the pad block 100 passes along the upper surface of the detection platform 600 and enters the detection station on the detection platform 600, and the double-layer release film 300 moves along the lower surface of the detection platform 600 to the blanking side for waiting. When the pad block 100 moves to the inspection station, conveyance is suspended, and inspection of the pad block 100 on the movable film 400 is performed. After the detection, the movable film 400 is continuously conveyed to move until the movable film 400 moves to the blanking side along the upper surface of the detection platform 600, and is attached to the groove on the double-layer release film 300 again at the blanking side.

In the detection process, the back adhesive layer 200 is not in direct contact with the detection platform 600, so that the back adhesive layer 200 is prevented from being adhered to the detection platform 600 in the detection process, the detected conductive gasket can be easily taken out, the detection efficiency is improved, and the back adhesive layer 200 is not damaged in the detection process, so that all the conductive gaskets can be detected, and the yield is improved.

In this embodiment, the movable film 400 and the double-layer release film 300 may be separated by manual peeling, or may be automatically peeled by a peeling device. For example, referring to fig. 5, a first inclined surface may be disposed on the feeding side of the detection platform 600; the sharp angle between the first inclined surface and the bottom surface is aligned with the gap between the movable film 400 and the double-layer release film 300, when the movable film 400 and the double-layer release film 300 pass through the sharp angle, the sharp angle is inserted into the gap between the movable film 400 and the double-layer release film 300, so that the movable film 400 moves to the upper surface of the detection platform 600 along the first inclined surface, and the double-layer release film 300 moves from the lower part of the first inclined surface to the discharging end of the detection platform 600.

In this embodiment, the discharge end of the detection platform 600 may be provided with a second inclined surface, and the movable film 400 moves out of the detection platform 600 along the second inclined surface, where the second inclined surface can play a role in guiding the movable film 400, so as to ensure that the movable film 400 can be accurately adhered to the original groove on the double-layer release film 300.

In a specific embodiment, the step of detecting the pad block attached to the movable film specifically includes:

and S310, compressing the pad block 100.

And S320, detecting the compression resistance value of the pad block 100.

S330, detecting the compression rebound stress of the pad block 100.

In this embodiment, the detection of the conductive pad generally includes the detection of the compression resistance, which is the measurement of the resistance value of the conductive pad when it is compressed, and the detection of the compression reaction force, which is the detection of the reaction force generated when the conductive pad is compressed.

Specifically, the pad block 100 is compressed, and when the pad block 100 is compressed, the contact resistance between the electrode on the detection platform 600 and the pad block 100 changes, and the compression resistance of the pad block 100 is detected by monitoring the change of the resistance value in real time. Meanwhile, the reaction force of the pad block 100 when being compressed is detected, thereby realizing the detection of the compression rebound stress of the pad block 100.

In one embodiment, after the movable film attached with the backing block is moved out of the detection station and adhered in the groove, the method further comprises:

and rolling the conductive gasket after detection.

Specifically, one end of the double-layer release film 300 passes through the lower part of the detection platform 600 from one side of the detection platform 600 and then is pulled to the other side of the detection platform 600; winding one end of the double-layer release film 300, and pulling the double-layer release film 300, so that the double-layer release film 300 moves towards the direction of the detection platform 600. The double-layer release film 300 is pulled in a winding mode, so that the detected release film can be wound and received while the pulling is realized, the process flow is simplified, and the detection efficiency is improved.

As a further embodiment of the present application, there is also disclosed a detection system for performing the detection method as described in any one of the above, and detecting the conductive pad as described in any one of the above; characterized in that the detection system comprises: the pressing detection module 500 is used for compressing and detecting the pad block 100; the detection platform 600 is arranged right below the pressing detection module 500 and is used for supporting the lining pad 100; and the conveying and winding module 700 is arranged on the blanking side of the detection platform 600 and is used for conveying the conductive gasket to the detection platform 600 and winding the detected conductive gasket.

The detection module of the embodiment is used for compressing the gasket block 100 and detecting the resistance value and compression rebound stress of the gasket block 100 when the gasket block 100 is compressed; the detection platform 600 is used for separating the movable membrane 400 from the double-layer release film 300 and supporting the separated movable membrane 400; the conveying and rolling module 700 is used for pulling the double-layer release film 300 to move and rolling the double-layer release film 300, the movable film 400 adhered to the double-layer release film 300 and the gasket block 100 adhered to the movable film 400.

In particular, the hold-down detection module 500 may include a hold-down assembly, a resistance measurement device, and a rebound force measurement device. The hold-down assembly may include a spring or gas cylinder that can adjust the pressure, which can precisely control the pressure applied to the pad block 100; the resistance measuring means may include a power source, a measuring instrument, and an electrode in contact with the pad block 100. When the gasket block 100 is compressed, the contact resistance between the electrode and the gasket block 100 can be changed, and the change of the resistance value can be monitored in real time through a measuring instrument; the rebound force measuring device may comprise a gauge and a force sensor in contact with the backing block 100. When a compressive force is applied to the pad block 100, the pad block 100 generates a reaction force, and the value of the reaction force is detected and recorded by the sensor.

In this embodiment, the conveying and winding module 700 includes a rotating shaft. When the conductive pad needs to be detected, one end of the double-layer release film 300 is wound on the rotating shaft, the rotating shaft is started, the rotating shaft is wound on one end of the double-layer release film 300, the double-layer release film 300 moves towards the direction of the detection platform 600, when the movable film 400 is close to the detection platform 600, the movable film 400 and the double-layer release film 300 are separated, the separated part of the movable film 400 and the double-layer release film 300 gradually moves onto the detection platform 600, after the movable film 400 moves to a preset position, the pressing component is controlled to compress a pad block on the movable film 400, and then the resistance measuring device is controlled to detect resistance change between the pad block 100 and an electrode of the detection platform. Meanwhile, the resistance measuring device is controlled to detect the compression rebound stress of the spacer block, and after the detection is completed, the rotating shaft pulls the double-layer release film 300 to continue to move until the movable film 400 on the detection platform 600 moves out of the detection platform 600 and is attached to the double-layer release film 300 again.

In this embodiment, the pressing component, the resistance measuring device, and the rebound force measuring device are integrated on the pressing detection module 500, so that the controllable flow is reduced, and the detection efficiency is improved.

In this embodiment, the pressing component is provided with a plurality of detection heads 510, a plurality of detection heads 510 are in one-to-one correspondence with a plurality of pad blocks 100, and a plurality of detection heads 510 are respectively connected with the resistance measuring device and the rebound force measuring device, so as to realize multi-station detection. And the detection efficiency is improved.

In summary, the conductive pad of the present embodiment includes a pad 100, a backing layer 200, a dual-layer release film 300 and a movable film 400 stacked in order, where the dual-layer release film 300 is provided with a groove, and the movable film 400 can be repeatedly bonded in the groove; the pad block 100 is adhered to the movable film 400 through the adhesive-backed layer 200, and the release force between the adhesive-backed layer 200 and the movable film 400 is smaller than the release force between the adhesive-backed layer 200 and the bottom surface of the groove. By bonding the gum layer 200 to the movable film 400 for detection, bonding to the detection platform 600 in the gum layer 200 detection process is avoided, and the performance of all products can be automatically checked on the premise of not damaging the gum layer 200 of the products, so that the detection efficiency is improved, and each product of the shipment is ensured to meet the performance requirement.

It should be noted that, without conflict, the embodiments of the present application and features of the embodiments may be combined with each other.

It should be noted that, the specific structure and working principle of the present invention are described by taking the conductive pad, the detection method and the detection system as examples, but the application of the present embodiment is not limited to the conductive pad, the detection method and the detection system, and can be applied to the production and the use of other similar workpieces.

It is to be understood that the invention is not limited to the precise arrangements and instrumentalities shown in the drawings, which have been described above, and that various modifications and changes may be effected without departing from the scope thereof. The scope of the invention is limited only by the appended claims.

The foregoing description of the preferred embodiments of the invention is not intended to limit the invention to the precise form disclosed, and any such modifications, equivalents, and alternatives falling within the spirit and scope of the invention are intended to be included within the scope of the invention.

Claims (10)

1. A conductive pad comprising:

The bottom surface of the pad block comprises a first area and a second area, and the second area is used for conducting current with the detection platform during detection;

the back adhesive layer is arranged in the first area;

the double-layer release film is provided with a groove;

The movable film is arranged in the groove and can be repeatedly bonded with the bottom surface of the groove;

The pad piece is adhered to the movable film through the gum layer, and the release force between the gum layer and the movable film is smaller than that between the gum layer and the bottom surface of the groove.

2. The conductive liner of claim 1, wherein the movable film is elongated, and the long side of the movable film is parallel to the long side of the double-layered release film.

3. The conductive pad of claim 2, wherein a central region of the bottom surface of the pad is the first region, an edge region of the bottom surface of the pad is the second region, a side of the backing layer parallel to the short side of the movable film is the first side, a side of the pad parallel to the short side of the movable film is the second side, a width of the movable film is greater than a side length of the first side, and a width of the movable film is less than a side length of the second side.

4. The conductive pad of claim 2 wherein said spacer block and said backing layer are bonded to form a pad body, said pad body being provided in plurality and a plurality of said pad bodies being spaced along a long side of said movable membrane.

5. The conductive gasket of claim 1 wherein the dual layer release film comprises a first release film and a second release film, the first release film is bonded to the second release film, the first release film is provided with a hollowed-out area, and the hollowed-out area and the second release film enclose the groove.

6. A detection method for detecting the conductive pad according to any one of claims 1 to 5; the method is characterized by comprising the following steps of:

Peeling the movable film attached with the lining pad from the groove;

conveying the movable film attached with the lining pad to a detection station;

Detecting the pad block attached to the movable film;

and moving the movable film attached with the lining pad out of the detection station and bonding the movable film in the groove again.

7. The method according to claim 6, wherein the step of conveying the movable film attached with the spacer block to a detection station comprises:

The movable film is pulled to enter a detection station from the feeding side of the detection platform through the upper surface of the detection platform;

And the double-layer release film is pulled to be conveyed to the blanking side of the detection platform from the feeding side of the detection platform through the lower surface of the detection platform.

8. The method according to claim 6, wherein the step of detecting the pad block attached to the movable film comprises:

Compressing the pad block;

detecting a compression resistance value of the pad block;

And detecting the compression rebound stress of the gasket block.

9. The method of claim 6, wherein after the moving film attached with the spacer block is moved out of the inspection station and bonded in the groove, further comprising:

and rolling the conductive gasket after detection.

10. A detection system for performing the detection method according to any one of claims 1-5, and detecting the conductive pad according to any one of claims 1-5; characterized in that the detection system comprises:

The pressing detection module is used for compressing and detecting the gasket block;

the detection platform is arranged right below the downward-pressing detection module and is used for supporting the lining pad;

and the conveying and winding module is arranged on the blanking side of the detection platform and used for conveying the conductive gasket to the detection platform and winding the detected conductive gasket.