CN216391960U - Electromagnetic interference shielding film - Google Patents

Abstract

The utility model discloses an electromagnetic interference shielding film, which comprises an insulating layer, a first bonding layer, a porous metal layer and a conductive adhesive layer, wherein the first bonding layer is a bonding layer comprising one resin of epoxy resin, acrylic resin, urethane resin, silicone rubber resin, poly-p-xylene resin, bismaleimide resin, styrene-ethylene-butylene-styrene block copolymer, polyimide or polyamide imide; the porous metal layer is a metal layer containing a plurality of micropores with the diameter of 1-120 mu m; the porous metal layer has a porosity of 15-30% and a tensile strength of not less than 20 kgf-mm²And the elongation is more than or equal to 5 percent. The utility model has the advantages of good surface insulation, high surface hardness, good chemical resistance, high heat resistance, high shielding performance, high bonding strength, good operability, low transmission loss, high transmission quality and good product reliability.

Description

Electromagnetic interference shielding film

Technical Field

The utility model belongs to the technical field of circuit printing plates, and particularly relates to an electromagnetic interference shielding film.

Background

In the market demand for electronic and communication products to have more sophisticated functions, the structure of the circuit substrate needs to be more compact and slim, while in the function, powerful and high-speed signal transmission is required. Since electronic signal transmission is faster and denser, the circuit density is increased, the distance between the substrate circuits is closer, and the applied frequency is toward a higher and wider band, so that the Electromagnetic Interference (EMI) situation is more and more serious, and therefore, the Electromagnetic Compatibility (EMC) must be effectively managed, so as to maintain the normal signal transmission of the electronic product and improve the reliability. The characteristics of being light, thin and Flexible at will make the Flexible Printed Circuit (FPC) play a very important role in the development of portable information and communication electronic industry.

As electronic communication products are getting smaller, the flexible printed circuit board is driven to bear more and more powerful functions, and on the other hand, as portable electronic products are moving to microminiature, and the demand of high-density FPC technology is also driven, under the condition that the function is required to be powerful, high-frequency, high-density and thin-line, shielding films for thin-film FPC are already put forward in the market at present, and are widely adopted in small electronic products such as mobile phones, digital cameras and digital cameras.

Based on the requirements of product beauty, surface protection and the like, the electromagnetic interference shielding film relies on the design of a black polyimide film. Because most of the polyimide films on the market are prepared by a tape casting process at present, the film size stability of the uniaxial extension method can not meet the industrial requirement, and the biaxial extension method is required for preparation, so that the difficulty and the requirement of equipment and a manufacturing process are improved. In addition, due to the design of light and thin electronic products, a thickness of 5 to 7.5 μm is usually required to reduce the thickness requirement of the rear-end FPC multi-layer board process for the flexible board material. However, at such an extremely thin thickness, it is difficult to achieve the low gloss surface (i.e. less than 25 GU), and the general properties of mechanical strength, workability and bendability cannot meet the current industry specifications, and the yield is not good.

In order to solve the above-mentioned problems of the thin polyimide film, an epoxy resin or polyurethane ink layer is usually used in combination with a release film to obtain an insulating layer with a thin thickness and a low-gloss surface. However, the mechanical strength, insulation, hardness of the ink layer; the properties such as chemical resistance and heat resistance are generally inferior to those of a black polyimide film. In addition, in order to provide sufficient release force, the release agent in the release film contains organic silicon, and after the release film is stripped, the organic silicon may remain on the surface contacting the release film, which results in the decrease of the reliability of the subsequent electroplating process.

In addition, as the demand for the emi shielding performance is higher, the thickness of the metal layer in the emi shielding film is higher, however, the disadvantage thereof is also exhibited as the thickness is increased. The solder heat resistance and Surface Mount Technology (SMT) process testing of EMI shielding films is particularly significant. For example, when the conductive resistance between the large-area exploded board of the dip soldering test after the curing process, the large-area exploded board of the shielding film after the SMT process, or the SMT process circuit is significantly increased under normal conditions, and the shielding metal layer with a higher thickness is used in combination with the insulating layer and the conductive adhesion layer with a thinner thickness, the weather resistance problem is caused, for example, the conductive resistance under the high-temperature and high-humidity environment or the cold and hot shock test condition is significantly increased, the adhesion force is reduced, and even the shielding metal layer may be delaminated.

SUMMERY OF THE UTILITY MODEL

The utility model mainly solves the technical problem of providing an electromagnetic interference shielding film which has the advantages of good surface insulation, high surface hardness, good chemical resistance, high heat resistance, high shielding performance, high bonding strength, good operability, low transmission loss, high transmission quality and good product reliability.

In order to solve the technical problems, the utility model adopts a technical scheme that: an electromagnetic interference shielding film comprises an insulating layer, a first adhesion layer, a porous metal layer and a conductive adhesive layer, wherein the first adhesion layer is positioned between the insulating layer and the porous metal layer, and the porous metal layer is positioned between the first adhesion layer and the conductive adhesive layer;

the insulating layer is an insulating layer with the hardness of 2H-6H;

the first adhesive layer is an epoxy adhesive layer, an acrylic adhesive layer, a urethane resin adhesive layer, a silicone rubber resin adhesive layer, a parylene resin adhesive layer, a bismaleimide resin adhesive layer, a styrene-ethylene-butylene-styrene block copolymer adhesive layer, a polyimide adhesive layer or a polyamideimide adhesive layer;

the porous metal layer is a metal layer containing a plurality of micropores with the diameter of 1-120 mu m;

the porous metal layer has a porosity of 15-30% and a tensile strength of not less than 20kgf/mm²And the elongation is more than or equal to 5 percent;

the conductive adhesive layer is provided with conductive particles;

the thickness of the electromagnetic interference shielding film is 11-70 μm, wherein the thickness of the insulating layer is 3-10 μm, the thickness of the first adhesion layer is 3-20 μm, the thickness of the porous metal layer is 2-15 μm, and the thickness of the conductive adhesive layer is 3-25 μm.

Further, the insulating layer is positioned between the carrier layer and the first adhesion layer;

the surface roughness of the contact surface of the carrier layer and the insulating layer is 0.001-10 μm;

the thickness of the carrier layer is 12.5-250 μm.

Furthermore, the insulating layer is an insulating layer with the gloss of 0-40GU after being torn off from the carrier layer.

Further, the porous metal layer is a copper layer, an aluminum layer, a lead layer, a nickel layer, a cobalt layer, a tin layer, a silver layer, an iron layer or a gold layer.

Further, the conductive adhesive layer is an epoxy resin conductive adhesive layer, an acrylic resin conductive adhesive layer, a phenolic resin conductive adhesive layer, a polyurethane conductive adhesive layer, a polyimide conductive adhesive layer or a polyamideimide conductive adhesive layer;

the conductive particles in the conductive adhesive layer are copper conductive particles, silver conductive particles, nickel conductive particles, tin conductive particles, gold conductive particles, palladium conductive particles, aluminum conductive particles, chromium conductive particles, titanium conductive particles, zinc conductive particles or carbon conductive particles.

Further, the insulating layer is a polyimide resin layer or a polyimide varnish layer.

The second adhesive layer is positioned between the porous metal layer and the conductive adhesive layer;

the second adhesive layer is an epoxy adhesive layer, an acrylic adhesive layer, a phenol adhesive layer, a polyurethane adhesive layer, a polyimide adhesive layer, or a polyamideimide adhesive layer.

The utility model has the following beneficial effects:

1. the electromagnetic interference shielding film has the advantages of good surface insulation, high surface hardness, good chemical resistance, high heat resistance, high shielding performance, high bonding strength, good operability, low transmission loss, high transmission quality, good product reliability and the like, has low-glossiness (matte) appearance, and meets the requirements of rear-end application;

2. in addition, the electromagnetic interference shielding film of the utility model uses the porous metal layer to replace the metal layer used by the existing shielding film, the porous metal layer can reflect the electromagnetic wave, so that the porous metal layer can reflect most of radio frequency and microwave energy, and the transmitted component is extremely small, thereby effectively shielding the interference of electromagnetic wave radiation and eliminating the pollution of the electromagnetic wave radiation; moreover, the porous metal layer can obviously improve the overall soldering tin resistance of the shielding film, is beneficial to the reflow soldering process of a rear-end product, and can achieve the soldering tin heat resistance of more than 300 ℃;

3. the electromagnetic interference shielding film of the utility model uses the carrier layer and the insulating layer in a matching way, changes the surface roughness and the surface energy of the carrier layer and the insulating layer in the way of containing additives or surface treatment and the like, and can have enough shape separating force under the condition of not using a release film (namely, not adding a shape separating agent), thereby not generating the problem of organosilicon transfer;

4. the insulating layer used in the electromagnetic interference shielding film is made of polyimide varnish, has better surface insulating property compared with printing ink type insulating layers such as epoxy resin or polyurethane resin and the like, and can reach more than 10¹²Omega insulation resistance value, and has more impedance control ability, chemical resistance, solder resistance and surface hardness.

Drawings

FIG. 1 is one of the schematic structural diagrams of the present invention;

FIG. 2 is a second schematic structural diagram of the present invention.

Detailed Description

The following detailed description of the preferred embodiments of the present invention, taken in conjunction with the accompanying drawings, will make the advantages and features of the utility model easier to understand by those skilled in the art, and thus will clearly and clearly define the scope of the utility model.

Example (b): an electromagnetic interference shielding film 1, as shown in fig. 1, comprises an insulating layer 11, a first adhesion layer 12, a porous metal layer 13 and a conductive adhesive layer 14, wherein the first adhesion layer 12 is located between the insulating layer 11 and the porous metal layer 13, and the porous metal layer 13 is located between the first adhesion layer 12 and the conductive adhesive layer 14;

the insulating layer 11 is an insulating layer with the hardness of 2H-6H; the insulating layer 11 is an insulating layer containing at least one of a pigment and an inorganic additive;

the first adhesive layer 12 is an epoxy adhesive layer, an acrylic adhesive layer, a urethane resin adhesive layer, a silicone rubber resin adhesive layer, a parylene resin adhesive layer, a bismaleimide resin adhesive layer, a styrene-ethylene-butylene-styrene block copolymer adhesive layer, a polyimide adhesive layer, or a polyamideimide adhesive layer; the weight proportion of the resin in the first adhesion layer 12 is 40-100% of the total solid content;

the porous metal layer 13 is a metal layer containing a plurality of micropores with the diameter of 1-120 mu m;

the porous metal layer 13 has a porosity of 15-30% and a tensile strength of not less than 20kgf/mm²And the elongation is more than or equal to 5 percent;

the conductive adhesive layer 14 is a conductive adhesive layer with conductive particles 141; the weight proportion of the conductive particles 141 in the conductive adhesive layer 14 is 5-55% of the total solid content;

the thickness of the electromagnetic interference shielding film is 11-70 μm, wherein the thickness of the insulating layer 11 is 3-10 μm, the thickness of the first adhesion layer 12 is 3-20 μm, the thickness of the porous metal layer 13 is 2-15 μm, and the thickness of the conductive adhesive layer 14 is 3-25 μm. Preferably, the thickness of the electromagnetic interference shielding film is 14 to 43 μm, wherein the thickness of the insulating layer 11 is 3 to 10 μm, the thickness of the first adhesive layer 12 is 3 to 20 μm, the thickness of the porous metal layer 13 is 3 to 8 μm, and the thickness of the conductive adhesive layer 14 is 5 to 15 μm.

The carrier layer 10 is further included, the insulating layer 11 is positioned between the carrier layer 10 and the first adhesion layer 12, the surface roughness of the contact surface of the carrier layer 10 and the insulating layer 11 is 0.001-10 μm, preferably, the surface roughness of the contact surface of the carrier layer 10 and the insulating layer 11 is 0.001-2 μm, and the thickness of the carrier layer 10 is 12.5-250 μm. The carrier layer 10 includes a polypropylene (PP) carrier layer, a biaxially oriented polypropylene (BOPP) carrier layer, a parylene-based resin carrier layer, a Polyimide (PI) carrier layer, a Polyphenylene Sulfide (PPs) carrier layer, a polyethylene naphthalate (PEN) carrier layer, a Polyurethane (PU) carrier layer, or a Polyamide (PA) carrier layer.

The carrier layer 10 further comprises at least one inorganic additive selected from calcium sulfate, carbon black, silicon dioxide, titanium dioxide, zinc sulfide, zirconia, calcium carbonate, silicon carbide, boron nitride, alumina, talcum powder, aluminum nitride, glass powder, quartz powder and clay, and the particle size of the inorganic additive in the carrier layer 10 is 10-20 nm. The inorganic additive can make the carrier layer have various colors different from the colors of the natural materials of the carrier layer, and can improve the glossiness and the surface roughness of the carrier layer.

The gloss of the insulating layer 11 after peeling off from the carrier layer is 0-40 GU. Preferably, the gloss of the insulating layer 11 after peeling off the carrier layer is 0-25 GU.

The pigment in the insulating layer 11 comprises an inorganic pigment, an organic pigment or a combination thereof, wherein the inorganic pigment is cadmium red, cadmium lemon yellow, orange cadmium yellow, titanium dioxide, carbon black, black iron oxide or black complex inorganic pigment; the organic pigment is aniline black, perylene black, anthraquinone black, benzidine yellow pigment, phthalocyanine blue or phthalocyanine green, and the weight proportion of the inorganic pigment or the organic pigment in the insulating layer 11 is 0-50% of the total solid content.

The inorganic additive in the insulating layer 11 is at least one selected from calcium sulfate, carbon black, silicon dioxide, titanium dioxide, zinc sulfide, zirconium oxide, calcium carbonate, silicon carbide, boron nitride, aluminum hydroxide, aluminum oxide, talcum powder, aluminum nitride, glass powder, quartz powder and clay. The weight proportion of the inorganic additive in the insulating layer 11 is 0-50% of the total solid content. Preferably, the weight proportion of the inorganic additive in the insulating layer 11 is 0 to 20% of the total solid content.

The insulating layer 11 further comprises at least one flame retardant selected from organic additives, halogen-containing compounds, phosphorus-containing compounds, nitrogen-containing compounds and boron-containing compounds, and the weight proportion of the flame retardant in the insulating layer 11 is 1-40% of the total solid content. The weight proportion of the flame retardant in the insulating layer 11 is 5-35% of the total solid content.

The insulating layer 11 is a plurality of layers, which can further reduce the problem of defects possibly generated on the surface of the insulating layer. The insulating layer may be a single polyimide varnish layer containing the aforementioned pigments, inorganic additives, flame retardants, or combinations thereof, but is not limited thereto; alternatively, the insulating layer may be a double polyimide varnish layer, wherein one polyimide varnish layer is composed of polyimide and the other polyimide varnish layer is composed of the pigment, the inorganic additive, the flame retardant or the combination thereof. In addition, the insulating layer 11 may also be three, four, five or more layers, which is not limited to this. In the embodiment using the insulating layer as a plurality of layers, the insulating layer containing a higher content of additives (i.e., the pigment, the inorganic additive, the flame retardant or the combination thereof) is in contact with the carrier layer to increase the overall shielding and blackness of the emi shielding film, and the surface roughness of the insulating layer can be changed to make the carrier layer and the insulating layer more easily separated; the insulating layer in contact with the first adhesion layer 12 is an insulating layer with a low content of additives, which further improves the overall mechanical properties of the emi shielding film.

The conventional black insulating layer or polyimide resin has only a pencil hardness of HB to 2H, easily causing scratch problems, thereby affecting the appearance and mechanical properties thereof. In contrast, the insulating layer 11 has an improved hardness by adding the above-mentioned pigment, inorganic additive, organic additive and/or flame retardant, and a pencil hardness of 2H to 6H can be achieved. The insulating layer 11 may have a pencil hardness of 2H, 3H, 4H, 5H, or 6H, but is not limited thereto. In addition, the flame resistance and hardness of the insulating layer 11 can be adjusted by changing the proportions of the inorganic additives, organic additives and/or flame retardants or by changing the components in the inorganic additives and/or their proportions. Specifically, using titanium dioxide, silica, alumina, aluminum hydroxide, calcium carbonate or a mixture thereof as an inorganic additive, increasing the proportion of the above-mentioned composition in the inorganic additive, or increasing the content of the flame retardant can increase the flame resistance of the insulating layer 11; the hardness of the insulating layer 11 may be increased by using titanium dioxide, silicon dioxide, or a mixture thereof as an inorganic additive, or by increasing the ratio of the above-mentioned components in the inorganic additive. Preferably, the inorganic additive comprising aluminum hydroxide, aluminum oxide, calcium carbonate or a mixture thereof can improve the flame resistance of the insulating layer.

The pigment of the first adhesion layer 12 comprises an inorganic pigment, an organic pigment, or a combination thereof. The specific forms of the inorganic pigment and the organic pigment in the first adhesion layer 12 are the same as those of the inorganic pigment and the organic pigment in the insulating layer, and therefore are not described herein again.

The first adhesion layer 12 comprises at least one inorganic additive selected from calcium sulfate, carbon black, silicon dioxide, teflon, fluorine-containing resin, titanium dioxide, zinc sulfide, zirconium oxide, calcium carbonate, silicon carbide, boron nitride, aluminum oxide, talcum powder, aluminum nitride, glass powder, quartz powder and clay, and the particle size of the inorganic additive in the first adhesion layer 12 is 10-2000 nm. The total content of silica, carbon black, talc, calcium carbonate, glass powder and quartz powder is 0-50%, preferably 0-20%, based on the total weight of the inorganic additive.

The first adhesive layer 12 further includes at least one flame retardant selected from polyimide resins, organic powders, and flame retardant compounds. The flame retardant compound is at least one selected from the group consisting of halogen, phosphorus, nitrogen and boron compounds. The weight proportion of the flame retardant in the first adhesion layer 12 is 1-50% of the total solid content. Preferably, the weight proportion of the flame retardant in the first adhesive layer 12 is 5-35% of the total solid content.

The porous metal layer 13 is a copper layer, an aluminum layer, a lead layer, a nickel layer, a cobalt layer, a tin layer, a silver layer, an iron layer or a gold layer.

The conductive adhesive layer 14 is an epoxy resin conductive adhesive layer, an acrylic resin conductive adhesive layer, a phenolic resin conductive adhesive layer, a polyurethane conductive adhesive layer, a polyimide conductive adhesive layer or a polyamideimide conductive adhesive layer.

The conductive particles in the conductive adhesive layer 14 are copper conductive particles, silver conductive particles, nickel conductive particles, tin conductive particles, gold conductive particles, palladium conductive particles, aluminum conductive particles, chromium conductive particles, titanium conductive particles, zinc conductive particles, or carbon conductive particles.

The insulating layer 11 is a polyimide resin layer or a polyimide varnish layer. The polyimide varnish layer is a polyimide resin having an imide bond skeleton. The polyimide resin layer is at least one selected from the group consisting of polyimide, polyimide imide, polyimide ester, and polybenzimidazole, but not limited thereto.

As shown in fig. 2, a second adhesion layer is further included, and the second adhesion layer is located between the porous metal layer 13 and the conductive adhesive layer 14. The second adhesive layer is an epoxy adhesive layer, an acrylic adhesive layer, a phenol adhesive layer, a polyurethane adhesive layer, a polyimide adhesive layer, or a polyamideimide adhesive layer.

The surface of the conductive adhesive layer 14 is provided with a release layer 15, and the release layer 15 is one of the following three structures:

the first method comprises the following steps: the release layer 15 is a release film, the thickness of the release film is 25-100 μm, and the release film is at least one of a PET fluoroplastic release film, a PET silicone-containing release film, a PET matte release film and a PE release film;

and the second method comprises the following steps: the release layer 15 is release paper, the thickness of the release paper is 25-130 μm, and the release paper is PET laminating paper;

and the third is that: the release layer 15 is a carrier film layer, the thickness of the carrier film layer is 25-100 μm, and the surface of the carrier film is provided with an adhesive.

The preparation method of the electromagnetic interference shielding film comprises the following steps:

s1, preparing the porous metal layer 13: forming an aluminum layer on the film, carrying out release treatment on the surface of the aluminum layer, plating a metal layer on the surface of the aluminum layer subjected to the release treatment, wherein the plating mode is one selected from sputtering, evaporation and water plating, forming holes on the metal layer by microetching treatment, and forming a porous metal layer after peeling the film and the aluminum layer; in addition, one of ordinary skill in the art can form voids (i.e., holes) in the metal layer by a conventional microetching process, and adjust the diameter of the formed voids according to the need and actual demand. Specifically, the voids formed by the microetching are uniformly distributed in the metal layer structure, and have higher shielding performance compared with the metal layer with the through holes. Also, the porous metal layer 13 has uniformly distributed pores, and if the pores are formed only on the surface of the metal layer, the solder heat resistance may not be sufficient and the problem of plate explosion may not be avoided in the subsequent process.

S2, forming an insulating layer 11 on the surface of the carrier layer, and curing the insulating layer 11 at the temperature of 50-180 ℃; optionally coating and curing another insulating layer 11 on the cured insulating layer 11;

s3, forming a first adhesion layer 12 on the surface of the insulating layer 11;

s4, pressing the porous metal layer 13 on the surface of the first adhesion layer 12;

and S5, forming a conductive adhesive layer 14 on the surface of the porous metal layer 13.

The preparation method of the electromagnetic interference shielding film further comprises the following steps:

s6, forming a second adhesion layer on the surface of the porous metal layer 13;

and S7, forming the conductive adhesive layer 14 on the surface of the second adhesion layer.

The film is polyimide or ethylene terephthalate, the metal layer is at least one of a copper layer, an aluminum layer, a lead layer, a nickel layer, a cobalt layer, a tin layer, a silver layer, an iron layer and a gold layer, and the metal layer is preferably a copper layer.

Table 1 shows the results of testing the thickness and properties of each layer of examples 1 to 6 and comparative examples 1 to 3, examples 1 to 6 are emi shielding films according to the present invention, examples 1 to 6 show emi shielding films having a structure obtained by peeling off a carrier layer, and comparative examples 1 to 3 are prior art shielding films.

In the process of manufacturing the EMI shielding films of examples 1-6, a carrier layer having a thickness of 25 μm and a main component of polyethylene terephthalate (PET) was used, and carbon black was added in an amount of 5 wt% based on the total weight of the carrier layer, and the carrier layer had a surface roughness Rz of 0.00775 μm.

The insulating layers of examples 1 to 6 were polyimide varnish layers having a hardness of 4H, and examples 1, 2, 5 and 6 were double-layered insulating layers (in the data shown in table 1 below, the thickness of the insulating layers of examples 1, 2, 5 and 6 was the thickness after lamination of the double-layered insulating layers), one of the double-layered insulating layers of examples 1, 2, 5 and 6 was not added with an inorganic additive, and the double-layered insulating layer was composed of two layersThe other layer is formed by adding carbon black as inorganic additive in 10% of the total weight of the insulating layers, the insulating layer without inorganic additive contacts the first adhesion layer, and the other insulating layer contacts the carrier layer. The single-layer insulating layers of examples 3 and 4 contained carbon black as an inorganic additive in an amount of 10% by weight based on the total weight of the single-layer insulating layer. The porous metal layers of examples 1 to 6 were all copper foils, had a porosity of 25. + -. 2%, a tensile strength of 22kgf/mm2 and an elongation of 6%, and had pores with a diameter of 1 to 20 μm. Comparative examples 1 to 3 are copper foil layers without microetching, and the insulating layer of comparative example 1 is a polyurethane ink layer, and the insulating layers of comparative examples 2 and 3 are black polyimide film layers

DuPont^TM)。

Further, the first adhesive layers of examples 1 to 6 and comparative examples 1 to 3 were formed of polyimide, an epoxy resin, phthalic anhydride as a curing agent, and a flame retardant, and the curing agent was contained in an amount of 0.1% of the polyimide, the epoxy resin was contained in an amount of 2.4% and the flame retardant was contained in an amount of 6.3% based on the total weight of the first adhesive layers.

The conductive paste layers of examples 1 to 6 were each a composite resin containing conductive particles, which were formed by mixing an epoxy resin and an acrylic resin at a weight ratio of 1:1, and the conductive particles were metal particles of nickel, silver and copper, and the content of each metal particle was 15% based on the total weight of the conductive paste layer. The structures of examples 5 and 6 further include a second adhesive layer, which is a composite resin formed of an epoxy resin and an acrylic resin in a weight ratio of 1:1, between the porous metal layer and the conductive adhesive layer, so that the thickness of the conductive adhesive layer shown in table 1 is the sum of the thickness of the second adhesive layer and the thickness of the conductive adhesive layer.

The performance data shown in tables 1 and 2 were measured according to the following methods or standards:

gloss: samples having dimensions greater than 3X 8(cm X cm) were prepared, the gloss of the samples was measured in the longitudinal direction using a gloss meter, and the values of the gloss meter were read at 60 degrees.

Resistance value: samples of 30mm × 514mm (longitudinal × transverse) were prepared, measurement was performed using a palm-type digital four-point probe, 2 sets were measured in the transverse direction of the sample, and 3 sets were measured in the longitudinal direction of the sample, and 6 sets of data were averaged.

Insulation resistance value: the measurement was performed at the stage of the semi-finished product on which the metal layer had not been plated, the semi-finished product was cut into a size of 30X 21(cm X cm) (about A4 size), an electrolytic copper foil having a thickness of about 0.035mm (about 1OZ) was coated and press-fitted on the semi-finished product, and a sample was obtained after aging at 160 ℃ for about 1 hour. Measurements were made on the left, middle and right halves of the insulating layer of the sample using an ohm meter and the average of the three sets of values was taken.

Peel strength: the measurement was carried out according to IPC-TM-6502.4.9D.

EMI shielding performance: the measurement is carried out according to GB/T30142-2013 'method for measuring the shielding effectiveness of planar electromagnetic shielding material'.

Solder heat resistance: the measurement was carried out according to IPC-TM-6502.4.13F.

Simulating an SMT process: the flexible printed circuit board is attached to the electromagnetic interference shielding film to be used as a sample, the temperature change curve of the sample simulating the SMT process is heated to 150 ℃ at the speed of 2 ℃/second and is maintained at 150-190 ℃ within 120 seconds, then the temperature is heated to 245 +/-5 ℃ at the speed of 3 ℃/second and is maintained for 30 seconds, and finally the temperature is cooled to room temperature at the speed of 4 +/-2 ℃/second.

Surface roughness: the measurement was carried out according to JIS-B0601 using an Atomic Force Microscope (AFM).

Separating force: the measurement was performed using a tensile tester according to ASTM D3330.

Table 1:

the test results in table 1 show that the emi shielding film of the present invention has better emi shielding performance, SMT process simulation test, and on-resistance and weather resistance after SMT process than the conventional shielding film.

Table 2 shows the effect of the content of the inorganic additive on the properties of the insulating layer and the carrier layer in examples 7 to 20 and comparative example 4, so that the structure of examples 7 to 20 and comparative example 4 was the carrier layer, the insulating layer and the first adhesive layer without the metal layer and the conductive adhesive layer in this order, and examples 7 to 20 and comparative example 4 each provided a structure having 2 different inorganic additive compositions. The insulating layers in examples 7-20 and comparative example 4 were each a 5 μm single-layer polyimide varnish layer, the support layers were each 25 μm polyethylene terephthalate, the additives were as shown in table 2, and the first adhesive layers of examples 7-20 and comparative example 4 were the same as those used in examples 1-6 and comparative examples 1-3. Further, the pigments contained in the insulating layer and the carrier layer of examples 7 to 20 and comparative example 4 were black pigments having 50% of black iron oxide, 15% of acid black 220, 20% of aniline black, 10% of carbon black, and 5% of titanium black, based on the total weight of the black pigments.

Table 2:

from the test results of table 2, it was confirmed that by adjusting the kind and/or content of the inorganic additive added, the surface roughness of the insulating layer and the supporting layer, and thus the release force between the supporting layer and the insulating layer, can be changed. The insulating layer and the carrier layer, which did not contain any inorganic additives as shown in comparative example 4, had an excessive peeling force between the carrier layer and the insulating layer, resulting in failure to peel off smoothly, i.e., the carrier layer was separated from the electromagnetic interference shielding film, and a peeling agent was additionally added. In addition, since the insulating layer is formed on the carrier layer in contact therewith, the surface roughness of the carrier layer affects the surface roughness of the insulating layer. Therefore, the carrier layer with higher surface roughness can be used to make the roughening effect of the insulating layer better.

The above description is only an embodiment of the present invention, and not intended to limit the scope of the present invention, and all equivalent structural changes made by using the contents of the present specification and the drawings, or applied directly or indirectly to other related technical fields, are included in the scope of the present invention.

Claims (7)

1. An electromagnetic interference shielding film, characterized in that: the adhesive tape comprises an insulating layer, a first adhesion layer, a porous metal layer and a conductive adhesive layer, wherein the first adhesion layer is positioned between the insulating layer and the porous metal layer, and the porous metal layer is positioned between the first adhesion layer and the conductive adhesive layer;

the insulating layer is an insulating layer with the hardness of 2H-6H;

the first adhesive layer is an epoxy adhesive layer, an acrylic adhesive layer, a urethane resin adhesive layer, a silicone rubber resin adhesive layer, a parylene resin adhesive layer, a bismaleimide resin adhesive layer, a styrene-ethylene-butylene-styrene block copolymer adhesive layer, a polyimide adhesive layer or a polyamideimide adhesive layer;

the porous metal layer is a metal layer containing a plurality of micropores with the diameter of 1-120 mu m;

the porous metal layer has a porosity of 15-30% and a tensile strength of not less than 20kgf/mm²And the elongation is more than or equal to 5 percent;

the conductive adhesive layer is provided with conductive particles;

the thickness of the electromagnetic interference shielding film is 11-70 μm, wherein the thickness of the insulating layer is 3-10 μm, the thickness of the first adhesion layer is 3-20 μm, the thickness of the porous metal layer is 2-15 μm, and the thickness of the conductive adhesive layer is 3-25 μm.

2. The electromagnetic interference shielding film according to claim 1, wherein: the insulating layer is positioned between the carrier layer and the first adhesion layer;

the surface roughness of the contact surface of the carrier layer and the insulating layer is 0.001-10 μm;

the thickness of the carrier layer is 12.5-250 μm.

3. The electromagnetic interference shielding film according to claim 1, wherein: the insulating layer is an insulating layer with the glossiness of 0-40GU after being torn off from the carrier layer.

4. The electromagnetic interference shielding film according to claim 1, wherein: the porous metal layer is a copper layer, an aluminum layer, a lead layer, a nickel layer, a cobalt layer, a tin layer, a silver layer, an iron layer or a gold layer.

5. The electromagnetic interference shielding film according to claim 1, wherein: the conductive adhesive layer is an epoxy resin conductive adhesive layer, an acrylic resin conductive adhesive layer, a phenolic resin conductive adhesive layer, a polyurethane conductive adhesive layer, a polyimide conductive adhesive layer or a polyamide-imide conductive adhesive layer;

the conductive particles in the conductive adhesive layer are copper conductive particles, silver conductive particles, nickel conductive particles, tin conductive particles, gold conductive particles, palladium conductive particles, aluminum conductive particles, chromium conductive particles, titanium conductive particles, zinc conductive particles or carbon conductive particles.

6. The electromagnetic interference shielding film according to claim 1, wherein: the insulating layer is a polyimide resin layer or a polyimide varnish layer.

7. The electromagnetic interference shielding film according to claim 1, wherein: the second adhesion layer is positioned between the porous metal layer and the conductive adhesive layer;

the second adhesive layer is an epoxy adhesive layer, an acrylic adhesive layer, a phenol adhesive layer, a polyurethane adhesive layer, a polyimide adhesive layer, or a polyamideimide adhesive layer.

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