KR20210038838A - Structure and manufacturing method of chip scale package for backlight application with high color gamut sensitive to moisture - Google Patents

Abstract

The present invention discloses a structure of a chip scale package for a backlight application with a high color gamut sensitive to moisture, which has a double-layer package structure, and the inner layer is a fluorescent adhesive film containing KSF phosphor powder; The outer layer is a transparent adhesive film containing an inorganic filler, and first, LED flip chips are arrayed on a substrate; A fluorescent adhesive film containing KSF phosphor powder is conformally adhered to five surfaces of the chip by vacuum; Cutting the bottom film along the outer vertical plane of the package; Secondary arraying the cut packages on the substrate; And packaging the organic silicon transparent adhesive film including the micron-sized inorganic filler with a vacuum laminate on the outer surface of the cut package, and finally, solidifying, and then cutting the chip scale package. The present invention has excellent moisture resistance, hardness, thermal conductivity and light attenuation prevention performance, can be used in high-power LED devices, and can improve the overall performance of the finished product of the CSP package.

Description

Structure and manufacturing method of chip scale package for backlight application with high color gamut sensitive to moisture

The present invention relates to the field of backlight technology, and in particular, to a chip scale package structure and manufacturing method for a backlight application in a high color gamut sensitive to moisture.

As the manufacturing technology of LED flip-chip CSP (chip scale package) matures, TFT-LCD (thin film transistor liquid crystal display), which uses a white light LED of CSP (chip scale package) as a backlight light emitting device, has gradually become mainstream, and has a high color gamut. For the display effect, a composition of KSF fluoride phosphor powder and β-SiAlON phosphor powder having a narrow half-width of the peak was used as the LED phosphor powder. When the KSF-based phosphor powder meets with water, it is deteriorated by a chemical reaction.The phosphor powder manufacturer performs a surface passivation treatment on the phosphor powder, but for long-term stability requirements, a simple surface treatment of the KSF phosphor powder prevents moisture intrusion. In other words, the general five-sided single-layer package structure does not realize the purpose of protecting the KSF phosphor powder. Accordingly, a structural design must be made in which a package material including KSF is placed in the inner layer of the package, and a cutting process using water as a cooling medium is excluded from the package manufacturing process.

Typically, backlight applications use medium or high power LED CSPs, which generate a lot of heat when the blue light emitted from the chip excites the phosphor powder, but with the low thermal conductivity of silica gel, packaged with a typical single-layer adhesive film. When the CSP of the surface is turned on at high power, the problem of loss of effect or change in chromaticity coordinates occurs due to cracking in the adhesive, so it is necessary to solve the heat dissipation problem of the package. Silicon, which has a relatively low hardness, scratches the surface of the package easily, and the operation performance of the classifier is low, so that the hardness of the package must be improved. Therefore, it is very important to develop a chip-scale package LED having moisture resistance, high hardness, and heat resistance.

It is an object of the present invention to provide a chip scale package structure and manufacturing method, and in particular, to provide a chip scale package structure and manufacturing method for a backlight application having a high color gamut sensitive to moisture.

A technical method for solving the technical problem of the present invention is as follows.

In a chip scale package structure (ie, a chip scale package structure) for a backlight application with a high color gamut sensitive to moisture, the structure has a double layer package structure, and the inner layer is a fluorescent adhesive film containing KSF phosphor powder; The outer layer is a transparent adhesive film containing an inorganic filler.

The thickness of the fluorescent adhesive film is 30-70um, and the thickness of the transparent adhesive film is 50-80um.

The manufacturing method of the chip scale package structure includes the following steps: Step (1), LED flip chips are arrayed on a substrate; Step (2), the fluorescent adhesive film containing the KSF phosphor powder is conformally adhered to the five sides of the chip by vacuum; Step (3), cut the bottom film along the outer vertical plane of the package; Step (4), secondary array of the cut packages on the substrate; Step (5) The organic silicon transparent adhesive film containing the micron-sized inorganic filler is packaged with a vacuum laminate on the outer surface of the cut package; Step (6), after solidification, the chip scale package is cut.

A fluorescent adhesive film containing KSF phosphor powder is prepared according to the following steps:

Step 1, A total of 20-99 parts by mass of Dow Corning high refractive index organic silicone package resin A, B, 1-80 parts by mass of KSF phosphor powder and 1-80 parts by mass of ß-SiAlON phosphor powder are uniformly mixed with a blender to prepare mixture 4 A step of obtaining, wherein each mass part is 1 g; Preferably, a total of 40-80 parts by mass of Dow Corning high refractive index organic silicone package resin A, B, 10-40 parts by mass of KSF phosphor powder, and 10-50 parts by mass of ß-SiAlON phosphor powder are used;

Step 2, Mixture 4 is extruded, coated or rolled on a release film to form a uniform film having a thickness of 30-70um.

In the transparent adhesive film containing an inorganic filler, the inorganic filler is 1-60 mass% (that is, the mass of the inorganic filler/the mass of the transparent adhesive film), and 10-60 mass% is preferable.

The inorganic filler is a micron-sized inorganic filler, and the general formula may be expressed as M _{(1-xyzu) + v} A _x B _y C _z D _u E _v O _{0.5 (1 + x + 2y + 3z + 3u)} , where , M=Na, K; A=Mg, Ca, Sr, Zn; B=B, Al, Ga; C=Si, Ge, Sn; D=Zr, Ti; E=F, Cl; The content of each element is, x <0.3; 0.1 < y &lt;0.3; 0.4 < z &lt;0.7; u <0.3; v <0.1, and x + y + z + uv> 0.1, and specific details are described in the applicant's earlier patent, 2019104635590.

A transparent adhesive film comprising an inorganic filler, that is, a transparent adhesive film comprising an inorganic filler of micron size, is prepared according to the following steps:

Step 1, 40-99 parts by mass in total, commercially available high refractive index organic silicone package resins A and B (for example, Dow Corning OE-6650 resin), 1-60 parts by mass of micron-sized inorganic filler (the two The sum is 100 parts by mass), uniformly mixed with a blender, kneader or kneader to obtain a mixture 1;

Step 2, Mixture 1 is extruded, coated, or rolled on a release film to form a uniform organic silicon transparent adhesive film having a thickness of 50-80um.

The transparent adhesive film containing the inorganic filler, that is, the transparent adhesive film containing the micron-sized inorganic filler, is also prepared by the following steps:

Step 1, 10-50 parts by mass of a phenyl vinyl silicone resin and 1-60 parts by mass of a micron-sized inorganic filler are uniformly mixed with a blender, kneader or kneader to obtain a mixture 2;

Here, the content of the vinyl group in the phenyl vinyl silicone resin is 0.001% by weight to 15% by weight, and the viscosity is 1,000-200,000 mPa.s;

Step 2, 0.00005 to 0.001 parts by mass of inhibitor, 0.1 to 5 parts by mass of tackifier, 3.0Х10-4 to 1.5Х10-3 parts by mass of Karstedt catalyst, hydrogen content of 0.1% to 1.6% by weight, viscosity of 5 Weighing -20,000 mPa·s of phenyl hydrogen-containing silicone oil, wherein the number of moles of Si-H in the phenyl hydrogen-containing silicone oil is 1.01-5 times the number of moles of vinyl groups in the mixture 2;

Add each component of step 3 and step 2 to mixture 2 (the sum of each component is 100 parts by mass), and mix uniformly with a blender, kneader or kneader to obtain mixture 3, and then extrude mixture 3, Rolled or coated to form an organic silicon transparent adhesive film having a thickness of 50-80um.

The manufacturing method of the chip scale package structure of the present invention is carried out according to the following steps:

Step (1), LED flip chips are arrayed on a substrate, and the wafer is fixed with a high-temperature tape having a heat resistance of 200°C or higher, and the number of LED chips (or LED wafers) is 1-10,000;

The size of the LED flip chip used in step (1) is 3535, 4040, 4545, or other size flip chip with a rated output of 1w or more;

Step (2), the fluorescent adhesive film 12 containing the KSF phosphor powder is conformally adhered to the five sides of the chip by vacuum;

The fluorescent adhesive film containing the phosphor powder of step (2) was made of Dow Corning's A/B two-component silica gel, and the amount of the phosphor powder added was 5-80% by weight (i.e., the mass of the phosphor powder/the fluorescent adhesive film. Mass), and by extrusion, rolling or coating, it is produced into a thin film having a thickness of 30-70um;

Cut the bottom film along the outer vertical plane of the package obtained in step (3), step (2);

Step (4), the cut package is secondarily arrayed on a substrate and packaged, and fixed with a high-temperature tape having a heat resistance of 200°C or higher;

Step (5), the arrayed packages package the (organic silicone) transparent adhesive film containing the micron-sized inorganic filler into a vacuum laminate;

The organic silicon transparent adhesive film containing the micron-sized inorganic filler used in step (5) is a commercially available A/B binary silica gel, for example, 40-99 parts of Dough Corning OE-6650A/B, 1- 60 parts of a micron-sized inorganic filler is uniformly mixed with a blender, kneader or kneader, and then extruded, rolled or coated to form an organic silicon transparent adhesive film having a thickness of 50-80um;

Step (6), after solidification in a 150°C oven, a chip scale package (CSP) package is cut to form a light source of a chip scale package for a backlight application with a high color gamut sensitive to moisture.

The transparent adhesive film of step (5) is a hot melt material, i.e., a silicone resin semi-cured prepolymer, and its rheological properties are as follows: In a plate test with a diameter D = 25 mm using a TA DHR rheometer, a vibration frequency of 1 Hz, strain 0.1% , Test temperature range 25°C-150°C, heating rate 5°C/min, storage factor G'20-2,000 KPa, loss factor 30-900 KPa, gel point appeared at 7.2min; The rheological properties should satisfy the viscosity of 6,000-8,000 mPa.s, the measurement temperature is 60°C, and the rotor rotation speed is 20 RPM.

Compared with the conventional technology, the present invention pre-prepares KSF phosphor powder and silicone adhesive into an ultra-thin fluorescent adhesive film (30-70um) through a double-layer package, and places it on the chip surface to be spaced apart from the package surface. , Re-packaging with a transparent fluorescent adhesive film containing a micron-sized inorganic filler prepared in advance on the outer layer.Since the inorganic filler has excellent moisture resistance, it sufficiently protects the KSF phosphor powder from being affected by moisture, and In the packaging process, the first two cutting processes were all carried out by dry cutting using a blade-shaped cutter.

The advantage of this structure is, first, the amount of heat generated in the inner layer ultra-thin structure is low, and it is easily transferred to the substrate so that heat is scattered; Second, since the micro-sized filler in the outer layer film contributes excellent heat resistance, the overall package structure has better heat resistance and can be used in high-power devices. In addition, the micro-sized filler in the outer layer film improves the hardness of the outer layer film, so that the packaged CSP has a higher hardness, thereby preventing the occurrence of scratches and making the operation of the classifier easier.

1 is a schematic structural diagram of a CSP emitting light from five general planes, 1-flip chip; An organic silicone adhesive film to which a 2-phosphor powder is added; It is a 3-phosphor powder particle.
2 is an exemplary diagram of a structure of a chip scale package for a backlight application in a high color gamut sensitive to moisture, and an 11-flip chip; A fluorescent adhesive film containing 12-KSF phosphor powder; A phosphor powder composition of 13-KSF and ß-SiAlON; An organic silicon transparent adhesive film containing a 14-micron-sized inorganic filler; It is a 15-micron inorganic filler.
3 is a flowchart of a method of manufacturing a chip scale package structure for a backlight application having a high color gamut sensitive to moisture according to the present invention.

Hereinafter, the present invention will be described in detail with reference to Examples as a relief chuck. Those of ordinary skill in the art can easily understand the advantages of the present invention according to the following description. In describing the specifics of the present invention, the scope of protection of the present invention is not limited by the specific examples described below, and the experimental methods that do not present specific experimental conditions in the examples below are generally known conditions, Or it should be understood to be the manufacturer's recommended conditions. It should be understood that the numerical ranges presented in the examples are both ends of each numerical range and an arbitrary value therebetween, unless otherwise described in the present invention.

1 is a structural example of a CSP that emits light in the general five planes of the prior art, and an organic silicon adhesive film to which phosphor powder is added is installed on the outside of a flip chip. The structure of the chip scale package for a backlight application having a high color gamut sensitive to moisture according to the present invention is, as shown in FIG. 2, the fluorescent adhesive film 12 including the KSF phosphor powder is in conformal contact with the periphery of the flip chip 11, The thickness of the fluorescent adhesive film is 30um, 50um, 70um, and includes a phosphor powder composition 13 of KSF and ß-SiAlON; The outermost layer is an organic silicon transparent adhesive layer 14 containing a micron-sized inorganic filler, and since the micron-sized inorganic filler 15 contained therein has moisture resistance, it effectively protects the inner layer of KSF phosphor powder from being damaged. It can be done, and the thickness is 80um.

Each component used in the present invention is as follows:

(1) Fluorescent adhesive film adhesive, LF-1112A, LF-1112B, THE DOW CHEMICAL COMPANY.

(2) KSF and β-SiAlON phosphor powder, KR-3K01, GR-MW540K8SD, Denka Company Limited.

(3) Micron-sized inorganic filler, TLF-158, Tianjin Tecore Synchem Inc.

(4) Organic silicone layer adhesive, OE-6650A, OE-6650B, THE DOW CHEMICAL COMPANY.

(5) Flip chip, F36A-CB, HC Semitek Corporation.

(6) Anti-settling powder, DM-30, Tokuyama Chemicals (Zhejiang) Co., Ltd.

(7) Vacuum laminating device, VHP-200, Shenzhen Nitto Optical Co., Ltd.

(8) Classifier, LEDA.PNP M6500 MAPPING SORTER, Shenzhen Nitto Optical Co., Ltd.

(9) Blow dryer, DHG-9070A, Shanghai Yiheng Kexueyiqi, Co., Ltd.

(10) Precision dicing cutting machine, DS613, Shenyang Heyantech Co., Ltd.

The components of the fluorescent adhesive film used in the test in the following examples are as follows: 20 parts by weight of LF-1112A adhesive, 20 parts by weight of LF-1112B adhesive, 40 parts by weight of KR-3K01 phosphor powder, 20 parts by weight of GR-MW540K8SD phosphor After uniformly mixing the powder and the above constituents, it is coated with a fluorescent adhesive film having a thickness of 30 μm.

Components of the organic silicon transparent adhesive film including the micro-sized transparent filler used in the test in the following examples are as follows: a total of 39-98 parts by weight of OE-6650A/B, 1 part by weight of DM-30, 1-60 After uniformly mixing the inorganic filler having a micron size in parts by weight and the above constituents, it is coated with a transparent adhesive film having a thickness of 80 μm.

The manufacturing method of CSP used for the test in the following examples is as follows: After arranging the F36A-CB flip chip with an MPI classifier, the adhesive film was adhered on the chip with a vacuum laminating device, and dried at 150° C. for 2 hours with a blow dryer. After that, it is cut with a precision dicing cutter to form one CSP.

The structure of the chip scale package for a backlight application having a high color gamut sensitive to moisture of the present invention is, as shown in FIG. 2, the outermost layer is an organic silicon transparent adhesive layer 14 including an inorganic filler having a micron size, and the micron size included therein The inorganic filler 15 has excellent moisture resistance, and can provide sufficient protection so that the KSF phosphor powder of the inner layer is not damaged. Table 1 is a table showing the relationship between the amount of micron-sized inorganic filler added and the water absorption rate in the transparent adhesive film. The method of testing the water absorption rate is as follows: A transparent adhesive film with a thickness of 80 μm with different thicknesses of the micron-sized inorganic filler prepared in advance is cut into a stick of 50 mm*20 mm, and the weight M ₀ is measured, followed by boiling water. After being immersed in and boiled for 1 hour, the moisture on the surface of the adhesive film is removed with dust-free paper, and the weight M ₁ is measured again, and the boiling water absorption rate is calculated according to Formula 1 below. According to the measurement results, the boiling water absorption rate of the adhesive film to which the micron-sized inorganic filler is not added is the highest, and the boiling water absorption rate of the adhesive film including the micron-sized inorganic filler is lower as the content of the filler is higher.

[official]

Boiling water absorption rate = (M ₁ -M ₀ )/M ₀ *100%

Table 1. Relationship between the amount of micron-sized inorganic filler added and the water absorption rate

In the structure of the chip scale package for a backlight application having a high color gamut sensitive to moisture, the outermost layer is an organic silicon transparent adhesive layer 14 including an inorganic filler having a micron size, as shown in FIG. When the addition amount of the inorganic filler 15 is 1-60% by weight, the hardness of the organic film can be increased from ShoreD70 to ShoreD80, it is possible to prevent scratches in CSP, and is advantageous in the sorting operation of CSP finished products. For a transparent adhesive film having a thickness of 80 μm with different amounts of micron-sized inorganic fillers prepared in advance, a hardness test was performed with a ShoreD digital display hardness tester (Shanghai Shuangxu Electronics Co., Ltd.). Table 2 is a table showing the relationship between the addition amount and hardness of the micron-sized inorganic filler. The hardness increases with an increase in the amount of the micron-sized inorganic filler added.

Table 2. Relationship between the added amount of micron-sized inorganic filler and hardness

The structure of the chip scale package for a backlight application having a high color gamut sensitive to moisture of the present invention is, as shown in FIG. 2, the outermost layer is an organic silicon transparent adhesive layer 14 including an inorganic filler having a micron size, and the micron size included therein The inorganic filler 15 has excellent thermal conductivity and light attenuation prevention performance, and can be used in high-power LED devices of 1W or more. The thermal resistance test device below is a T3Ster thermal resistance tester (Shenzhen Manyoung Technology Co., Ltd.). Table 3 shows the relationship between the addition amount of the micron-sized inorganic filler and the thermal resistance.According to the results, the higher the amount of the micron-sized inorganic filler added to the outermost transparent layer, the lower the thermal resistance, that is, the thermal conductivity of the product. This would be better.

Table 3. Relationship between micron-sized inorganic filler addition amount and thermal resistance

The structure of the chip scale package for a backlight application having a high color gamut sensitive to moisture of the present invention is, as shown in FIG. 2, the outermost layer is an organic silicon transparent adhesive layer 14 including an inorganic filler having a micron size, and the micron size included therein The inorganic filler 15 of can improve the light emission efficiency of the finished CSP product. Table 4 shows the long distance for the double-layer structure CSP of the present invention (a 20% weight part micron-sized inorganic filler is added to the outer transparent adhesive layer) and the general double-layer structure CSP (i.e., CSP packaged with a KSF fluorescent layer and a general transparent layer). It is a comparison of the results of the long optical test, where the KSF phosphor layer of the inner layer is exactly the same. An LED626 gonio photometer (Hangzhou Yuanfang Photoelectric Information Co., Ltd) was used as a test instrument. The test range was C0-180 degrees, that is, the light intensity distribution data of -90 degrees to 90 degrees were measured, and the test interval was 1.0 degrees. According to the results, the double-layer structure CSP of the present invention has a higher light efficiency, a larger average light intensity diffusion angle, in other words, a better light emission form.

Table 4. Comparison results of a long-distance optical test of the double-layer structure CSP prepared by the present invention and the general double-layer structure CSP

As shown in Figure 2, the particle diameter of the micron-sized inorganic filler 15 of the present invention is: D10 is 1-3um, D50 is 10-15um, D90 is 40-50um, D97 is 60-70um. If the particle diameter is too large, protrusions are formed on the surface of the film prepared in advance due to the phosphor powder of large particles, the surface is rough after packaging with csp, and in severe cases, it affects the color temperature consistency of the csp package; When the particle diameter is too small, the effect of improving hardness, moisture resistance, and heat resistance is not remarkable.

As shown in Fig. 2, the amount of the inorganic filler 15 having a micron size of the present invention is 1-60% by weight, preferably 10-50% by weight. When the addition amount is less than 10%, the effect of improving moisture resistance, hardness, heat resistance, and light attenuation prevention is not remarkable; When the addition amount is higher than 50%, the viscosity of the entire organic silicon system is too high (>50000 mPa·s), and it is difficult to form a film in advance.

As shown in FIG. 2, a fluorescent adhesive film 12 including KSF phosphor powder is adhered to the periphery of the flip chip 11, and a KSF and β-SiAlON phosphor powder composition of DENKA (DENKA, Shanghai) is added.

3 is a flow chart of a method of manufacturing a chip scale package structure for a backlight application with a high color gamut sensitive to moisture of the present invention, and the manufacturing method includes the following steps:

Step (1), LED flip chips are arrayed on a substrate, and the wafer is fixed with a high-temperature tape having a heat resistance of 200 DEG C or higher;

Step (2), the fluorescent adhesive film 12 containing the KSF phosphor powder is conformally adhered to the five sides of the chip by vacuum;

Step (3), cut the bottom film along the outer vertical plane of the package;

Step (4), the cut packages are secondary arrayed on the substrate, and the package is fixed with a fixing tape having heat resistance of 200°C or higher;

Step (5), the arrayed packages package the organic silicon transparent adhesive film containing micron-sized inorganic fillers by vacuum lamination;

Step (6), after solidification in a 150°C oven, a chip scale package (CSP) package is cut to form a light source of a chip scale package for a backlight application with a high color gamut sensitive to moisture.

The size of the LED flip chip used in step (1) is 3535, 4040, or 4545, or a flip chip of another size with a rated output of 1w or more may be used.

The fluorescent adhesive film containing the KSF phosphor powder used in step (2) was made of Dow Corning's A/B two-component silica gel, and the amount of the phosphor powder added is 5-80% by weight, through extrusion, rolling, or coating. It is manufactured as a thin film with a thickness of 30-70um.

The organic silicon transparent adhesive film containing the micron-sized inorganic filler used in step (5) is commercially available A/B bi-component silica gel, for example, 40-99 parts of Dough Corning OE-6650A/B, 1- 60 parts of a micron-sized inorganic filler was uniformly mixed with a blender, kneader or kneader, and then extruded, rolled or coated to form an organic silicon transparent adhesive film having a thickness of 50-80 um.

For the CSP product manufactured according to the present invention, a CSP package having a single-layer adhesive film on 5 sides, and a double-layer package CSP product having a KSF fluorescent layer and a general transparent layer, a lighting aging test of 1000 hours was performed, and the comparison result is It is shown in Table 5. Here, the test conditions are as follows: the wafer is 55*55mil, the lighting voltage is 3V, and the current is 1500mA. In the test result, the smaller the ΔX and ΔY, which are the change values of CIE X and CIE Y, the better the product performance. After 1000 hours of lighting, it is immersed in red ink at 100℃ for 2 hours, and then checks whether red ink has soaked into the adhesive layer of the package. If ink is present, the performance is bad, and if there is no ink, the performance is good . According to the test results, red ink was present in both the surface package adhesive layer of the general five-sided single layer CSP and the general double-layer structure CSP (i.e., the KSF fluorescent layer and the general transparent layer packaged CSP), and the double-layer structure of the present invention There is no red ink in the surface package adhesive layer of CSP (20% by weight of micron-sized inorganic filler is added to the transparent adhesive layer of the outer layer).

Table 5. 1000 hour lighting aging test comparison data

The CSP package manufactured according to the above embodiment has excellent moisture resistance, heat resistance, and light attenuation prevention performance, has high hardness and light emission efficiency, and is suitable for a backlight application in a high color gamut sensitive to moisture.

By controlling each variable and material presented in the present invention, it is possible to realize a chip package structure having a performance similar to that of the present invention. Although the present invention has been described through the embodiments as described above, the scope does not depart from the core of the present invention. Simple modifications, modifications, or equivalents that can be obtained without creative efforts by those of ordinary skill in the art all fall within the scope of the claims to be described later.

Claims (10)

In the chip scale package structure for backlight applications with a high color gamut sensitive to moisture, which has a double-layer package structure and the inner layer is a fluorescent adhesive film containing KSF phosphor powder,
The outer layer is a transparent adhesive film including an inorganic filler; In the transparent adhesive film containing the inorganic filler, the inorganic filler is 1-60 mass%, the inorganic filler is a micron-sized inorganic filler, and the general formula is M _{(1-xyzu) + v} A _x B _y C _z D _u E _v O _{0.5 (1 + x + 2y + 3z + 3u)} , where M=Na, K; A=Mg, Ca, Sr, Zn; B=B, Al, Ga; C=Si, Ge, Sn; D=Zr, Ti; E=F, Cl; The content of each element is defined as x <0.3; 0.1 < y &lt;0.3; 0.4 < z &lt;0.7; u <0.3; v <0.1, and x + y + z + u-v> 0.1, and the thickness of the fluorescent adhesive film is 30-70um, and the thickness of the transparent adhesive film is 50-80um. Structure of a chip-scale package for backlight applications.
The method of claim 1,
In a transparent adhesive film containing an inorganic filler, a chip scale package structure for a backlight application with a high color gamut sensitive to moisture, characterized in that the inorganic filler is 10-60% by mass.
The method of claim 1,
Fluorescent adhesive film containing KSF phosphor powder,
Step 1, A total of 20-99 parts by mass of Dow Corning high refractive index organic silicone package resin A, B, 1-80 parts by mass of KSF phosphor powder and 1-80 parts by mass of β-SiAlON phosphor powder are uniformly mixed with a blender to prepare mixture 4 To obtain, step 1; -Each mass part is 1 g; Preferably, a total of 40-80 parts by mass of Dow Corning high refractive index organic silicone package resin A, B, 10-40 parts by mass of KSF phosphor powder, and 10-50 parts by mass of β-SiAlON phosphor powder are used;
Step 2, Mixture 4 is extruded, coated or rolled on a release film to form a uniform film having a thickness of 30-70um. The method of claim 1,
A transparent adhesive film containing an inorganic filler, that is, a transparent adhesive film containing an inorganic filler of a micron size,
A total of 40-99 parts by mass of commercially available high refractive index organic silicone package resins A and B (for example, Dow Corning OE-6650 resin), 1-60 parts by mass of a micron-sized inorganic filler (the sum of the two is 100 Mass parts), uniformly mixing with a blender, kneader or kneader to obtain a mixture 1, step 1;
Mixture 1 is extruded, coated or rolled on a release film to form a uniform organic silicon transparent adhesive film having a thickness of 50-80um, step 2; characterized in that it is produced in a high color gamut sensitive to moisture. Chip scale package structure.
The method of claim 1,
A transparent adhesive film containing an inorganic filler, that is, a transparent adhesive film containing an inorganic filler of a micron size,
Step 1 of obtaining mixture 2 after uniformly mixing 10-50 parts by mass of a phenyl vinyl silicone resin and 1-60 parts by mass of a micron-sized inorganic filler with a blender, kneader or kneader, and obtaining a mixture 2-vinyl group in the phenyl vinyl silicone resin The content of is 0.001% by weight-15% by weight, the viscosity is 1,000-200,000 mPa.s-;
0.00005 to 0.001 parts by mass of inhibitor, 0.1 to 5 parts by mass of tackifier, 3.0 Х10-4 to 1.5 Х10-3 parts by mass of Karstedt catalyst, hydrogen content of 0.1% to 1.6% by weight, viscosity of 5-20,000mPa Step 2, weighing the phenyl hydrogen containing silicone oil of .s, the number of moles of Si-H in the phenyl hydrogen containing silicone oil is 1.01-5 times the number of moles of vinyl groups in the mixture 2;
Add each component of step 2 to mixture 2 (the sum of each component is 100 parts by mass) and mix uniformly with a blender, kneader or kneader to obtain mixture 3, and then mixture 3 is extruded, rolled or coated To form an organic silicon transparent adhesive film having a thickness of 50-80um, Step 3; characterized in that produced in, moisture-sensitive high color gamut backlight application chip scale package structure. Arraying the LED flip chips over the substrate, step (1);
Step (2) of conformally bonding a fluorescent adhesive film containing KSF phosphor powder to five surfaces of the chip by vacuum;
Step (3), cutting the bottom film along the outer vertical plane of the package obtained in step (2);
A step (4) of secondary arraying and packaging the cut packages on a substrate;
A step (5) of packaging an organic silicon transparent adhesive film including an inorganic filler having a micron size on the outer surface of the cut package with a vacuum laminate;
After solidification, the chip scale package is cut to form a chip scale package light source for backlight applications with a high color gamut sensitive to moisture, characterized in that it is carried out according to step (6). Method of manufacturing a chip scale package structure for backlight applications of.
The method of claim 6,
In step (1), the wafer is fixed with a high-temperature tape having a heat resistance of 200°C or higher, and the number of LED chips (or LED wafers) is 1-10,000, and the size of the used LED flip chip is 3,535, 4,040, 4,545, or , Flip chips of different sizes with a rated output of 1w or more; In step (4), a method of manufacturing a chip scale package structure for a backlight application having a high color gamut sensitive to moisture, characterized in that the package is fixed with a high-temperature tape having a heat resistance of 200°C or higher.
The method of claim 6,
Fluorescent adhesive film containing the KSF phosphor powder of step (2),
A total of 20-99 parts by mass of Dow Corning high refractive index organic silicone package resin A, B, 1-80 parts by mass of KSF phosphor powder and 1-80 parts by mass of β-SiAlON phosphor powder are uniformly mixed with a blender to obtain mixture 4. , Step 1; -Each mass part is 1 g; Preferably, a total of 40-80 parts by mass of Dow Corning high refractive index organic silicone package resin A, B, 10-40 parts by mass of KSF phosphor powder, and 10-50 parts by mass of β-SiAlON phosphor powder are used;
A chip scale package for backlight applications with high color gamut sensitive to moisture, characterized in that the mixture 4 is extruded, coated, or rolled on a release film to form a uniform film having a thickness of 30-70um, which is produced in step 2; Method of making the structure.
The method of claim 6,
The transparent adhesive film including the inorganic filler of step (5), that is, the transparent adhesive film including the inorganic filler of micron size,
A total of 40-99 parts by mass of commercially available high refractive index organic silicone package resins A and B (for example, Dow Corning OE-6650 resin), 1-60 parts by mass of a micron-sized inorganic filler (the sum of the two is 100 Mass parts), uniformly mixing with a blender, kneader or kneader to obtain a mixture 1, step 1;
Mixture 1 is extruded, coated or rolled on a release film to form a uniform organic silicon transparent adhesive film having a thickness of 50-80um, step 2; characterized in that it is produced in a high color gamut sensitive to moisture. Method of manufacturing a chip scale package structure for use.
The method of claim 6,
The transparent adhesive film including the inorganic filler of step (5), that is, the transparent adhesive film including the inorganic filler of micron size,
Step 1 of obtaining a mixture 2 after uniformly mixing 10-50 parts by mass of a phenyl vinyl silicone resin and 1-60 parts by mass of a micron-sized inorganic filler with a blender, kneader or kneader, step 1-vinyl in the phenyl vinyl silicone resin The content of the group is 0.001% by weight-15% by weight, and the viscosity is 1000-200000mPa.s -;
0.00005 to 0.001 parts by mass of inhibitor, 0.1 to 5 parts by mass of tackifier, 3.0 Х10-4 to 1.5 Х10-3 parts by mass of Karstedt catalyst, hydrogen content of 0.1% to 1.6% by weight, viscosity of 5-20,000 mPa Step 2, weighing the phenyl hydrogen containing silicone oil of .s, the number of moles of Si-H in the phenyl hydrogen containing silicone oil is 1.01-5 times the number of moles of vinyl groups in the mixture 2;
Add each component of step 2 to mixture 2 (the sum of each component is 100 parts by mass) and mix uniformly with a blender, kneader or kneader to obtain mixture 3, and then mixture 3 is extruded, rolled or coated A method of manufacturing a chip scale package structure for a backlight application having a high color gamut sensitive to moisture, characterized in that it is manufactured in step 3, of forming an organic silicon transparent adhesive film having a thickness of 50-80um.

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