CN203923079U - Sheet photoreactive semiconductor device for photosemiconductor - Google Patents

Abstract

The utility model provides sheet photoreactive semiconductor device for photosemiconductor.Described photosemiconductor possesses the bonding coat being formed by the 1st silicone resin with sheet, and is arranged at the thickness direction one side of bonding coat, the non-bonding coat being formed by the 2nd silicone resin.

Description

Sheet photoreactive semiconductor device for photosemiconductor

Technical field

The utility model relates to sheet photoreactive semiconductor device for photosemiconductor, specifically, relates to and possesses photosemiconductor with sheet and pass through the optical semiconductor device of the optical semiconductor of sheet encapsulation for this photosemiconductor.

Background technology

Elastomeric silicone resin sheet is because the excellences such as weather resistance, thermotolerance are used to various uses.

This silicone resin sheet is because surface has binding property, and therefore when transportation, silicone resin sector-meeting is adhered to other members and around polluting, or needs stacked stripping film separately to protect surface.In addition, when surperficial binding property is too high, also exist the release sheet situation that release property reduces when the silicone resin sheet demoulding.

Therefore, proposed such as the silicone rubber plate for thermo-compressed obtaining at scale like powders such as surface distribution talcum, micas (for example, referring to following patent documentation 1.）。

The thermo-compressed of patent documentation 1 is passed through scattered powder with silicone rubber plate and is reduced surperficial binding property, reduces pollution around, and then improves release property.

Prior art document

Patent documentation

Patent documentation 1: Japanese kokai publication hei 10-219199 communique

Utility model content

The problem that utility model will solve

Yet the thermo-compressed that patent documentation 1 is recorded because scattered powder causes the transparency insufficient, therefore exists the luminous efficiency of the optical semiconductor device that so encapsulates optical semiconductor and obtain to reduce this rough sledding with silicon rubber sector-meeting.

The purpose of this utility model is to provide and reduces pollution around, improves sheet and the optical semiconductor device that suppressed the reduction of luminous efficiency for non-binding property and the excellent photosemiconductor of the transparency.

For the scheme of dealing with problems

Photosemiconductor of the present utility model is characterised in that to possess the bonding coat being formed by the 1st silicone resin with sheet, and is arranged at the thickness direction one side of aforementioned adhesion layer, the non-bonding coat being formed by the 2nd silicone resin.

This photosemiconductor, therefore can reduce because bonding coat is attached to the pollution that member around causes because the thickness direction at bonding coat simultaneously arranges non-bonding coat with sheet, improves non-binding property, improves the transparency simultaneously.

In addition, with sheet preferably, aforementioned the 2nd silicone resin is solid-state and is thermoplasticity photosemiconductor of the present utility model at normal temperatures.

At this photosemiconductor with in sheet, because the 2nd silicone resin is thermoplasticity, therefore can by heating make non-bonding coat and bonding coat closely sealed.Therefore, can prevent from producing gap between non-bonding coat and bonding coat.As a result, can further improve the transparency of sheet for photosemiconductor.

In addition, at photosemiconductor of the present utility model, with in sheet, preferably, aforementioned the 1st silicone resin is the Thermocurable silicone resin on B rank.

According to this photosemiconductor sheet, because the 1st silicone resin is the Thermocurable silicone resin on B rank, therefore can be easily and coating object positively.After coating object, by photosemiconductor is to C rank, positively encapsulated object thing with sheet heating.

In addition, at photosemiconductor of the present utility model, with in sheet, preferably, aforementioned the 2nd silicone resin is silsesquioxane.

According to this photosemiconductor sheet, because the 2nd silicone resin is silsesquioxane, therefore, in weather resistance and transparency excellence, can easily guarantee thermoplasticity.

In addition, at photosemiconductor of the present utility model, with in sheet, preferably, aforementioned silsesquioxane contains the functional group of reacting with aforementioned the 1st silicone resin.

At this photosemiconductor, with in sheet, because silsesquioxane contains the functional group of reacting with the 1st silicone resin, therefore by the 2nd silicone resin is reacted with the 1st silicone resin, can further improve the adaptation of bonding coat and non-bonding coat.

In addition, photosemiconductor of the present utility model is preferred for the encapsulation of optical semiconductor with sheet.

The encapsulation for optical semiconductor with sheet due to this photosemiconductor therefore can suppress the reduction of luminous efficiency in the reliability that improves optical semiconductor.

In addition, at photosemiconductor of the present utility model, with in sheet, preferably, aforementioned non-bonding coat is formed by the sheet being formed by aforementioned the 2nd silicone resin.

According to this photosemiconductor sheet, because non-bonding coat is formed by the sheet being formed by the 2nd silicone resin, it is hereby ensured the even thickness of non-bonding coat, in addition, long-term keeping quality is excellent.

In addition, at photosemiconductor of the present utility model, with in sheet, preferably, aforementioned non-bonding coat becomes stratiform by the granulated being formed by aforementioned the 2nd silicone resin.

According to this photosemiconductor sheet, because non-bonding coat becomes stratiform by granulated, therefore can be so that technique be simple.

In addition, optical semiconductor device of the present utility model is characterised in that, it possesses photosemiconductor with sheet and passes through the optical semiconductor of sheet encapsulation for aforementioned photosemiconductor, aforementioned photosemiconductor possesses the bonding coat being formed by the 1st silicone resin with sheet, and is arranged at the thickness direction one side of aforementioned adhesion layer, the non-bonding coat being formed by the 2nd silicone resin.

This optical semiconductor device, owing to possessing the optical semiconductor encapsulating with sheet by the excellent photosemiconductor of the transparency, therefore can suppress the reduction of luminous efficiency.

The effect of utility model

Photosemiconductor of the present utility model can reduce to be attached to member around and the pollution that causes by bonding coat with sheet, improves non-binding property, improves the transparency simultaneously.

Optical semiconductor device of the present utility model can suppress the reduction of luminous efficiency.

Accompanying drawing explanation

Fig. 1 (a) and Fig. 1 (b) are the process picture sheets of the manufacture method of the 1st embodiment of sheet for explanation photosemiconductor of the present utility model,

Fig. 1 (a) illustrates the operation of preparing respectively bonding coat and non-bonding coat,

Fig. 1 (b) illustrates the operation of bonding coat and the laminating of non-bonding coat.

Fig. 2 (a) and Fig. 2 (b) are that explanation is used the photosemiconductor shown in Fig. 1 (b) with sheet, as case chip, to manufacture the process picture sheet of the method for optical semiconductor device,

Fig. 2 (a) illustrates and will peel off the operation of the photosemiconductor of the 2nd release sheet with sheet configuration relative to substrate,

Fig. 2 (b) illustrates the operation with sheet encapsulation optical semiconductor by photosemiconductor.

Fig. 3 (a) and Fig. 3 (b) are that explanation is used photosemiconductor of the present utility model to use the 1st embodiment of sheet as the process picture sheet of the variation of the method for case chip manufacture optical semiconductor device,

Fig. 3 (a) illustrates and will peel off the operation of the photosemiconductor of the 1st release sheet with sheet configuration relative to substrate,

Fig. 3 (b) illustrates the operation with sheet encapsulation optical semiconductor by photosemiconductor.

Fig. 4 illustrates the sectional view of the 2nd embodiment of sheet for photosemiconductor of the present utility model.

Fig. 5 (a) and Fig. 5 (b) are that explanation is used the photosemiconductor of Fig. 4 with sheet, as case chip, to manufacture the process picture sheet of the method for optical semiconductor device,

Fig. 5 (a) illustrates and will peel off the operation of the photosemiconductor of the 2nd release sheet with sheet configuration relative to substrate,

Fig. 5 (b) illustrates the operation with sheet encapsulation optical semiconductor by photosemiconductor.

Fig. 6 (a) and Fig. 6 (b) are that explanation is used photosemiconductor of the present utility model to use the 2nd embodiment of sheet as the process picture sheet of the variation of the method for case chip manufacture optical semiconductor device,

Fig. 6 (a) illustrates and will peel off the operation of the photosemiconductor of the 1st release sheet with sheet configuration relative to substrate,

Fig. 6 (b) illustrates the operation with sheet encapsulation optical semiconductor by photosemiconductor.

Description of reference numerals

1 photosemiconductor sheet

2 bonding coats

3 non-bonding coats

6 optical semiconductor devices

8 optical semiconductors

Embodiment

The 1st embodiment

In Fig. 1, take paper above-below direction as above-below direction (thickness direction, the 1st direction), take paper left and right directions as left and right directions (the 2nd direction, with the direction of the 1st direction quadrature), take paper thickness direction as fore-and-aft direction (the 3rd direction, with the direction of the 1st direction and the 2nd direction quadrature).Fig. 2 and subsequent each figure are as the criterion with above-mentioned direction.

In Fig. 1 (b), the non-bonding coat 3 that photosemiconductor possesses bonding coat 2 with sheet 1 and is arranged at the upper surface of bonding coat 2 (thickness direction one side).In addition, at bonding coat 2, be arranged with the 1st release sheet 4.In addition, on non-bonding coat 3, be provided with the 2nd release sheet 5.

Bonding coat 2 is layered in the upper surface of the 1st release sheet 4, is formed the sheet of extending along face direction (with the direction of thickness direction quadrature, be left and right directions and this both direction of fore-and-aft direction) by the 1st silicone resin.

As the 1st silicone resin, such as listing: thermoplastic silicone resin, Thermocurable silicone resin etc.Can preferably list Thermocurable silicone resin.

As Thermocurable silicone resin, such as listing: two stage solidification type silicone resins, one-phase curing type silicone resin etc.

Two stage solidification type silicone resins are to have two stage reaction mechanism, in the reaction of first stage B rank (semicure), and the Thermocurable silicone resin of C rank in the reaction of subordinate phase (completely curing).On the other hand, one-phase curing type silicone resin is the reaction mechanism with one-phase, completely crued Thermocurable silicone resin in the reaction of first stage.

In addition, B rank are Thermocurable silicone resin states between liquid A rank and completely crued C rank, are to solidify and gelation is only carried out a little, the little state of Young's modulus on modular ratio C rank.

As Thermocurable silicone resin, can preferably list two stage solidification type silicone resins.

In addition, also can prepare the 1st silicone resin (being specially Thermocurable silicone resin) by the organosilicon resin composition that contains Multiple components (being specially Thermocurable organosilicon resin composition).

As the uncured bulk of two stage solidification type organosilicon resin compositions (first stage solidify before), for example, can enumerate condensation reaction addition reaction curing type silicone resin combination.

Condensation reaction addition reaction curing type silicone resin combination is to carry out by heating the Thermocurable organosilicon resin composition of condensation reaction and addition reaction, more specifically, be can carry out condensation reaction by heating to reach B rank (semicure), then can carry out the Thermocurable organosilicon resin composition that addition reaction (concrete example is as being hydrosilylation reactions) reaches C rank (completely curing) by further heating.

This condensation reaction addition reaction curing type silicone resin combination preferably remains functional group can addition or can condensation, more preferably remain can addition functional group.

As functional group that can addition reaction, can list: the thiazolinyl of carbon numbers 2～10 such as vinyl, allyl group, propenyl, butenyl, pentenyl, hexenyl, heptenyl, octenyl, the cycloalkenyl group of carbon numbers such as cyclohexenyl, norbornene 3～10 etc.The thiazolinyl that can preferably list carbon number 2～5, more preferably lists vinyl.And then the functional group as can addition reaction, also can enumerate for example silicon hydrogen base (SiH).

Functional group that can addition reaction can be used singly or in combination.

Functional group as can addition reaction, can preferably list the combination of alkenyl and silicon hydrogen base.

On the other hand, as functional group that can condensation reaction, such as listing: silicon hydrogen base, silanol group (Si-OH), halogen atom (specifically having bromine atoms, chlorine atom, fluorine atom, iodine atom etc.), alkoxyl group (specifically having methoxyl group, oxyethyl group, propoxy-, isopropoxy, butoxy, isobutoxy, pentyloxy, hexyloxy etc.), phenoxy group or acetoxyl group etc.

Functional group as can condensation reaction, can preferably list silicon hydrogen base, silanol group.

In addition, silicon hydrogen base can double as can addition reaction functional group and functional group that can condensation reaction.

Functional group that can condensation reaction can be used singly or in combination.

Functional group as can condensation reaction, can preferably list the combination of silicon hydrogen base and silanol group.

As this condensation reaction addition reaction curing type silicone resin combination, such as enumerating the middle composition for silicone resins of recording such as TOHKEMY 2012-82320 communique etc.

Bonding coat 2 is preferably formed by the Thermocurable silicone resin (composition) on B rank.

The Young's modulus of bonding coat 2 at 25 ℃ is for example more than 0.01MPa, more than being preferably 0.025MPa, and is for example, below 1.0MPa, to be preferably below 0.5MPa.The Young's modulus of bonding coat 2 is used nano impress instrumentation fixed.The Young's modulus of non-bonding coat 3 described later is also measured by same method.

If the Young's modulus of bonding coat 2 is more than above-mentioned lower limit, can guarantee the shape-holding property of bonding coat 2, improve the operability of bonding coat 2.If the Young's modulus of bonding coat 2 is below the above-mentioned upper limit, encapsulating optical semiconductor 8(described later referring to Fig. 2) time, positively coating optical semiconductor 8.

In addition, for the transmittance of bonding coat 2, when thickness is 600 μ m, with respect to the light of wavelength 500nm, for example, be more than 80%, to be preferably more than 85%, more preferably more than 90%, more preferably more than 95%, and, be below 99.99%.The transmittance of bonding coat 2 is according to JIS K7361-1(1997 version) the record of " test method of the total light transmittance of plastics-transparent material ", by the spectrophotometric determination of integrating sphere is housed.Transmittance for non-bonding coat 3 described later is also measured by same method.

In addition, bonding coat 2 has viscosity (binding property) when normal temperature (being specially 25 ℃, lower same).For example, bonding coat 2 with respect to polypropylene (PP) sheet (without stretching.Thickness 50 μ m) the peel adhesion of 25 ℃ is for example more than 0.3N/2cm, more than being preferably 1N/2cm, and is for example, below 8N/2cm, to be preferably below 5N/2cm.

Wherein, the peel adhesion of bonding coat 2 can describe in detail in the embodiment below.For non-bonding coat 3 photoreactive semiconductors described later, by the peel adhesion of sheet 1, also by same method, measure.

The thickness of bonding coat 2 is for example more than 50 μ m, more than being preferably 100 μ m, and is for example below 2000 μ m, is preferably below 1500 μ m.

Non-bonding coat 3 forms by the sheet being formed by the 2nd silicone resin.

As the 2nd silicone resin, such as listing: silsesquioxane, organic silicon granule etc.Can preferably list silsesquioxane.

Structure to " Si-O-Si " skeleton of silsesquioxane is not particularly limited, such as listing: cage type, trapezoidal, random shape etc.

As silsesquioxane, such as listing: poly methyl silsesquioxane, polyphenylmethyl base silsesquioxane, polyphenylsilsesquioxane etc.Can preferably list poly methyl silsesquioxane.

In addition, silsesquioxane also can contain the functional group with the functional group reactions of the 1st silicone resin at molecule.Particularly, silsesquioxane can contain the functional group with the functional group reactions can addition or can condensation of the 1st silicone resin at molecule.

As the functional group of containing in silsesquioxane, such as listing: vinyl, hydroxyl etc.Can preferably list vinyl.

The 2nd silicone resin can be used commercially available product, particularly, as poly methyl silsesquioxane, can enumerate chemical company of KR-220L(SHIN-ETSU HANTOTAI manufactures) etc., in addition, as containing vinyl poly methyl silsesquioxane, can list: production code member 52365-8(Aldrich manufactures), OL1123(Hybrid Plastics, Inc. manufactures) etc.

The 2nd silicone resin is solid-state at normal temperatures and is thermoplastic.

Particularly, the softening temperature of the 2nd silicone resin is for example more than 60 ℃, to be preferably more than 70 ℃, and is for example, below 200 ℃, to be preferably below 150 ℃.

If softening temperature is below the above-mentioned upper limit,, when thermo-compressed described later, can positively make non-bonding coat 3 softening.And then, can easily make the softening melting of non-bonding coat 3, at optical semiconductor 8 Bondings described later, during in substrate 7, can prevent the damage of lead-in wire.On the other hand, if softening temperature is more than above-mentioned lower limit, can improve the operability under normal temperature.

The softening temperature of the 2nd silicone resin is measured as follows: the 2nd silicone resin of about 1g is placed on hot-plate, by making the 2nd silicone resin softening hot-plate heating with 5 ℃/min of intensification temperature, with this process of visual observation, measures thus.

In addition, non-bonding coat 3 is inviscid (not having binding property) at normal temperatures.

The Young's modulus of non-bonding coat 3 at 25 ℃ is for example more than 0.5MPa, more than being preferably 1MPa, and is for example, below 15MPa, to be preferably below 10MPa.

For the transmittance of non-bonding coat 3, in the situation that thickness is 10 μ m, with respect to the light of wavelength 500nm, for example, be more than 80%, to be preferably more than 85%, more preferably more than 90%, more preferably more than 95%, and be below 99.99%.

The thickness of non-bonding coat 3 is for example more than 0.1 μ m, more than being preferably 1 μ m, and is for example below 100 μ m, is preferably below 50 μ m.

As the 1st release sheet 4, can list: polymer sheets such as polyolefin piece (polythene strip, PP sheet etc.), polyester chips (PET sheet etc.), ceramic plate for example, such as tinsel etc.Can preferably list polymer sheet.In addition, also can implement to the surface of the 1st release sheet 4 (lower surface) lift-off processing such as fluorine processing.

The 2nd release sheet 5 is by being formed with the same material of the 1st release sheet 4.In addition, also can implement the lift-off processing same with the 1st release sheet 4 to the 2nd release sheet 5.

Then, this photosemiconductor is described by the manufacture method of sheet 1.

In the method, first, as shown in the downside figure of Fig. 1 (a), bonding coat 2 is layered on the 1st release sheet 4.

Particularly, the varnish being formed is coated on to the upper surface of the 1st release sheet 4 by the 1st silicone resin, then, heating is filmed, and forms bonding coat 2 thus on the 1st release sheet 4.In addition, when the 1st silicone resin contains condensation reaction addition reaction curing type silicone resin combination, by heating, film condensation reaction is carried out.Thus, bonding coat 2 is formed by the Thermocurable silicone resin on B rank.

In addition, prepare separately non-bonding coat 3.

Particularly, as shown in the upside figure of Fig. 1 (a), non-bonding coat 3 is layered in to (wherein,, in Fig. 1 (a), the relative position for clear and definite and bonding coat 2, is formed on its D score for convenience) on the 2nd release sheet 5.

Want non-bonding coat 3 to be formed on the 2nd release sheet 5, referring to the upside figure of Fig. 1 (a), first, the 2nd silicone resin is dissolved in to solvent and prepares solution, then, solution coat is formed and filmed at the upper surface of the 2nd release sheet 5.

As solvent, can list: varsols such as hexane, heptane, ketones solvents such as acetone, methylethylketone.

Solids component in solution (the 2nd silicone resin) concentration is for example more than 10 quality %, more than being preferably 25 quality %, and is for example below 90 quality %, is preferably below 75 quality %.

Then, by adding the solvent of heat abstraction in filming.

Be for example more than 0.1 minute, to be preferably more than 0.5 minute heat-up time, and be for example, below 100 minutes, to be preferably below 50 minutes.In addition, Heating temperature is for example more than 50 ℃, to be preferably more than 75 ℃, and is for example, below 150 ℃, to be preferably below 120 ℃.

Thus, the upper surface at the 2nd release sheet 5 forms non-bonding coat 3.

Then, as shown in Fig. 1 (b), by bonding coat 2 and non-bonding coat 3 laminatings.

Particularly, the bonding coat 2 being layered on the 1st release sheet 4 is spun upside down with the non-bonding coat 3(being layered on the 2nd release sheet 5 the non-bonding coat 3 that is layered in the upper surface of the 2nd release sheet 5) attach.

In the attaching of bonding coat 2 and non-bonding coat 3 by they crimping.Pressure during crimping is for example more than 0.001MPa, and is for example, below 300MPa, to be preferably below 50MPa.

On the other hand, in the attaching of bonding coat 2 and non-bonding coat 3, according to the binding property of bonding coat 2, also stacked on bonding coat 2 (being specially mounting) non-bonding coat 3 only.

Thus, obtain at thickness direction by the 1st release sheet 4 and the 2nd release sheet 5 sheet 1 for photosemiconductor clamping, that formed by bonding coat 2 and non-bonding coat 3.There is the 2nd release sheet 5 the upper surface of non-bonding coat 3 is stacked, in addition, have the 1st release sheet 4 the lower surface of bonding coat 2 is stacked.

Just manufacture the upper surface of sheet 1 for the photosemiconductor of (be specially from making 30 minutes with interior, lower with), be non-bonding coat 3 one sides face with respect to polypropylene (PP) sheet (without stretching.Thickness 50 μ m) the peel adhesion of 25 ℃ is for example, below 0.40N/2cm, to be preferably below 0.20N/2cm, more preferably below 0.10N/2cm, more preferably below 0.05N/2cm, and is for example more than 0.001N/2cm.

The photosemiconductor of just having manufactured is the sheet 1 for photosemiconductor except the 1st release sheet 4 and the 2nd release sheet 5 with sheet 1() with respect to the transmittance of the light of wavelength 500nm, be for example more than 80.0%, be preferably more than 90.0%, more preferably more than 92.5%, more preferably more than 95.0%, and be less than 100%.

Then, the photosemiconductor of Fig. 1 good to firm manufacture (b) operates with sheet 1, that is, specifically preserve for a long time and/or transport (circulation).That is, from photosemiconductor shown in Fig. 1 (b) with the manufacture of sheet 1 afterwards to transportation and then to before soon use, be arranged at sheet 1 for photosemiconductor to major general's the 2nd release sheet 5.In other words, being about to use the photosemiconductor of Fig. 1 (b) with before sheet 1, as shown in the long and short dash line of Fig. 1 (b), the 2nd release sheet 5 is peeled off from non-bonding coat 3.

Then, with reference to Fig. 2, to describing by the method that sheet 1 encapsulates to manufacture optical semiconductor device 6 as case chip to optical semiconductor 8 with this photosemiconductor.

In the method, first, as shown in the long and short dash line of Fig. 1 (b), the 2nd release sheet 5 is peeled off from non-bonding coat 3.

Then, as shown in Figure 2 (a) shows, sheet 1 configuration relative to substrate 7 for photosemiconductor of the 2nd release sheet 5 will have been peeled off.

Particularly, by the photosemiconductor after the photosemiconductor of having peeled off the 2nd release sheet 5 as shown in the long and short dash line of Fig. 1 (b) is spun upside down with sheet 1 with sheet 1(referring to Fig. 2 (a)) non-bonding coat 3 relative with the optical semiconductor 8 of upper surface that is installed on substrate 7.

Substrate 7 is substantially planar, particularly, and by having the plywood of the conductor layer (not shown) that comprises electrode pad (not shown) and wiring (not shown) to be formed as circuit pattern is stacked on insulated substrate.Insulated substrate, such as being formed by silicon substrate, ceramic substrate, polyimide resin substrate etc., is preferably ceramic substrate, specifically by sapphire substrate, is formed.

Conductor layer is formed by conductors such as gold, copper, silver, nickel.In addition, from the angle of electroconductibility, electrode pad is preferably formed by silver, copper.The thickness of substrate 7 is for example more than 30 μ m, more than being preferably 50 μ m, and is for example below 1500 μ m, is preferably below 1000 μ m.

Optical semiconductor 8 is arranged on light-emitting diode or the laser diode of the upper surface of substrate 7.Optical semiconductor 8 carries out flip-chip installation connection or Bonding connection with respect to the electrode pad of substrate 7, is electrically connected to thus with conductor layer.Optical semiconductor 8 is the elements (being specially blue led) that for example send blue light.The thickness of optical semiconductor 8 is for example more than 0.05mm and below 1mm.

Then,, as shown in Fig. 2 (b), by photosemiconductor, use sheet 1 to bury (coating) optical semiconductor 8 underground.

Particularly, to substrate 7 sheet 1 for thermo-compressed photosemiconductor.

Preferably photosemiconductor is carried out to flat board compacting with sheet 1 and substrate 7.

As pressing conditions, temperature is more than the plasticization temperature of non-bonding coat 3, particularly, being equal to or higher than the softening temperature of the 2nd silicone resin of non-bonding coat 3, specifically, for example, is more than 80 ℃, be preferably more than 100 ℃, and be for example, below 220 ℃, to be preferably below 200 ℃.In addition, pressure is for example more than 0.01MPa, and is for example, below 1MPa, to be preferably below 0.5MPa.Press time is for example 1～10 minute.

By this thermo-compressed, as shown in Fig. 2 (b), there is softening melting and mutually fuse with bonding coat 2 in non-bonding coat 3, more specifically, forms the encapsulated layer 9 of fully integratedization.So optical semiconductor 8 is embedded in encapsulated layer 9.That is, the packed layer in the upper surface of optical semiconductor 8 and side 9 coating.

The packed layer of upper surface 9 coating of the substrate 7 exposing from optical semiconductor 8 in addition.

Thus, by sheet 1(encapsulated layer 9 for photosemiconductor) adhere to optical semiconductor 8 and substrate 7.

Then,, by this thermo-compressed, during the Thermocurable silicone resin that contains B rank at bonding coat 2, bonding coat 2 reaches C scalariform state (completely curing).

More specifically, in the situation that bonding coat 2 is condensation reaction addition reaction curing type silicone resin combination, residual functional group's (being specially hydroxyl) that can addition reaction is when residual, in bonding coat 2, carry out addition reaction, and when non-bonding coat 3 contains above-mentioned functional group (being specially vinyl), the functional group of the functional group of bonding coat 2 and non-bonding coat 3 carries out addition reaction (being specially addition reaction of silicon with hydrogen).

Encapsulated layer 9 is inviscid at normal temperatures.The Young's modulus of encapsulated layer 9 at 25 ℃ is for example more than 0.001MPa, and is for example, below 0.3MPa, to be preferably below 0.1MPa.

In addition, Young's modulus as encapsulated layer 9 at 25 ℃, can be with reference to the evaluation of embodiment described later, photosemiconductor is heated at 150 ℃ to the Young's modulus of the encapsulated layer 9 after 3 hours with sheet 1, evaluate, Young's modulus is now for example more than 0.5MPa, more than being preferably 1MPa, and be for example, below 15MPa, to be preferably below 10MPa.

In addition,, when the thickness of encapsulated layer 9 is 600 μ m, with respect to the transmittance of the light of wavelength 500nm, is for example more than 80%, to be preferably more than 85%, and is for example, below 99.9%, to be preferably below 99%.

Thus, obtain using sheet 1 to encapsulate the optical semiconductor device 6 of optical semiconductor 8 by photosemiconductor.

Then, as required, as shown in the long and short dash line of Fig. 2 (b), the 1st release sheet 4 is peeled off from non-bonding coat 3.

So, at this photosemiconductor, with in sheet 1, because the upper surface at bonding coat 2 as shown in Fig. 1 (b) arranges non-bonding coat 3, therefore can reduce because bonding coat 2 is attached to the pollution that member around causes, improve non-binding property.Particularly, can improve non-binding property with respect to the 2nd release sheet 5, with respect to the non-binding property (the non-binding property when wind up roll is pulled out photosemiconductor with sheet 1) of the 1st release sheet 4.

In addition, at the photosemiconductor shown in Fig. 1 (b), with in sheet 1, by the 2nd release sheet 5, can also prevent that the foreign matters such as dust are attached to bonding coat 2, and then, the impact of external impact when protection photosemiconductor is not transported with sheet 1.

In addition, can reduce or cancel space that photosemiconductor needs with the transport point of sheet 1, be specially so far for preventing from being attached to the space of other members, preserve efficiently or transport a large amount of sheets 1 for photosemiconductor.

In addition, can improve the transparency of sheet 1 for photosemiconductor.

In addition, at this photosemiconductor, with in sheet 1, because the 2nd silicone resin is thermoplasticity, the heating while therefore suppressing in the encapsulation by optical semiconductor 8, can make non-bonding coat 3 closely sealed with bonding coat 2.Therefore, can prevent from producing gap between non-bonding coat 3 and bonding coat 2.As a result, can further improve the transparency of sheet 1 for photosemiconductor.

In addition, at this photosemiconductor, with in sheet 1, if the 1st silicone resin is the Thermocurable silicone resin on B rank, can easily and positively buries (coating) object underground, be specially optical semiconductor 8.Then,, after coating object, specifically, after encapsulation optical semiconductor 8, heating photosemiconductor becomes C rank with sheet 1, can positively encapsulate optical semiconductor 8 thus.

In addition, at this photosemiconductor, with in sheet 1, if the 2nd silicone resin of non-bonding coat 3 is silsesquioxane, can in weather resistance and transparency excellence, easily guarantee above-mentioned thermoplasticity.

At this photosemiconductor, with in sheet 1, if silsesquioxane contains the functional group of reacting with the 1st silicone resin, by the 2nd silicone resin is reacted with the 1st silicone resin, can further improve the adaptation of bonding coat 2 and non-bonding coat 3.

In addition, the encapsulation for optical semiconductor 8 with sheet 1 due to this photosemiconductor therefore can suppress the reduction of luminous efficiency in the reliability that improves optical semiconductor 8.

In addition, according to this sheet 1 for photosemiconductor, because non-bonding coat 3 forms by the sheet being formed by the 2nd silicone resin, it is hereby ensured the even thickness of non-bonding coat 3, and long-term keeping quality is excellent.

In addition, this optical semiconductor device 6, owing to possessing the optical semiconductor 8 encapsulating with sheet 1 by the excellent photosemiconductor of the transparency, therefore can suppress the reduction of luminous efficiency.

Variation

The 1st embodiment, as shown in the solid line of Fig. 1 (b), operates (specifically preserve for a long time and/or transport) to be laminated with the photosemiconductor of the 2nd release sheet 5 on non-bonding coat 3 with sheet 1.That is, the photosemiconductor shown in the solid line of Fig. 1 (b) arrive transportation with the manufacture of sheet 1 and then afterwards to before being about to use freely, is arranged at sheet 1 for photosemiconductor to major general's the 2nd release sheet 5.

Yet, also can as shown in the long and short dash line of Fig. 1 (b), first, from the photosemiconductor of just having manufactured, with the non-bonding coat 3 of sheet 1, peel off the 2nd release sheet 5, then, directly to having peeled off the photosemiconductor of the 2nd release sheet 5, with sheet 1, operate.

In addition, the sheet 1 for photosemiconductor of can reeling, specifically referring to Fig. 1 (b), the 1st release sheet 4(that makes non-bonding coat 3 be present in bonding coat 2 and be layered on this bonding coat 2 is not shown) between, be retracted to web-like (not shown in Fig. 1 (b)), can successfully pull out sheet 1 for photosemiconductor from this volume.

This sheet 1 for photosemiconductor, because the 2nd release sheet 5 is peeled off in advance, has therefore realized slimming if, can efficiently photosemiconductor be retracted to web-like with sheet 1.

In addition, in the 1st embodiment, in encapsulation, during optical semiconductor 8, bonding coat 2 and non-bonding coat 3 fuse mutually, and for example also can be as shown in the dotted line of Fig. 2 (b), mutually do not fuse and make a distinction.Now, non-bonding coat 3 is formed on the upper surface of optical semiconductor 8 and side and the upper surface of the substrate 7 that exposes from optical semiconductor 8 continuously.

And then, in the 1st embodiment, as shown in Figure 2, by photosemiconductor, use sheet 1 that the optical semiconductor 8 that is installed in advance substrate 7 is buried underground and encapsulated, though and be not shownly attached at sheet 1 for photosemiconductor such as also can will being installed on substrate 7 by the optical semiconductor 8 such as supports such as brace tables (not shown).

In the 1st embodiment, as shown in Figure 2 (a) shows, make non-bonding coat 3 relative with optical semiconductor 8, and for example also can, as shown in Fig. 3 (a), make bonding coat 2 relative with optical semiconductor 8.

Now, first, do not make the photosemiconductor of Fig. 1 (b) spin upside down with sheet 1, as shown in the long and short dash line and dash-dot arrows of Fig. 3 (a), this photosemiconductor is peeled off the 1st release sheet 4 with the bonding coat 2 of sheet 1 certainly.Thus, the lower surface that exposes bonding coat 2.

Then, make bonding coat 2 relative with optical semiconductor 8.

Then, as shown in Figure 3 (b), by photosemiconductor, use sheet 1 to bury (coating) optical semiconductor 8 underground.Particularly, with respect to substrate 7 sheet 1 for thermo-compressed photosemiconductor.

Thus, upper surface and the side of bonding coat 2 coatings and encapsulation optical semiconductor 8.

Obtain thus optical semiconductor device 6.

In addition, also can be in the 1st silicone resin and/or the 2nd silicone resin absorb fillers and/or fluor (aftermentioned).

As weighting agent, such as listing: silicon-dioxide (silica), barium sulfate, barium carbonate, barium titanate, titanium oxide, zirconium white, magnesium oxide, zinc oxide, ferric oxide, aluminium hydroxide, calcium carbonate, stratiform mica, carbon black, diatomite, glass fibre, silicone resin particulate etc.

Fluor so long as there is the particle of wavelength Conversion function and for optical semiconductor device 6(is referring to Fig. 2 (b)) in the known fluor that uses be just not particularly limited, such as listing: blue light can be converted to sodium yellow yellow fluorophor, blue light can be converted to the known fluor such as red-emitting phosphors of red light.

As yellow fluorophor, can list: Y for example ₃a _l5o ₁₂: Ce(YAG(yttrium aluminum garnet): Ce), Tb ₃a _l3o ₁₂: Ce(TAG(terbium aluminium garnet): Ce) etc. there is the carbuncle type fluor of carbuncle type crystalline structure, such as oxynitride fluor such as Ca-α-SiAlON etc.

As red-emitting phosphors, for example, can list CaAlSiN ₃: Eu, CaSiN ₂: the nitride phosphors such as Eu etc.

In addition, weighting agent and fluor are particulate state, its shape are not particularly limited, such as listing roughly spherical, substantially planar, needle-like etc. roughly.The mean value median size of the maximum length of weighting agent and fluor (referring to median size when roughly spherical) is for example more than 0.1 μ m, more than being preferably 0.2 μ m, and is for example below 500 μ m, is preferably below 200 μ m.

The compounding ratio of weighting agent and fluor is adjusted to the degree of the effect (being specially the transparency) that does not hinder excellence of the present utility model, particularly, with respect to the 1st silicone resin and/or the 2nd silicone resin 100 mass parts, be for example more than 0.01 mass parts, more than being preferably 1 mass parts, and be for example, below 80 mass parts, to be preferably below 70 mass parts.

The 2nd embodiment

In Fig. 4 and Fig. 5, the member for same with the 1st embodiment, is marked with identical Reference numeral, and description is omitted.

In the 1st embodiment, as shown in Figure 1, by sheet, form non-bonding coat 3, but also can as shown in Figure 4, by granulated, become stratiform.

As shown in Figure 4, the non-bonding coat 3 of stratiform that photosemiconductor possesses bonding coat 2 with sheet 1 and is arranged on the upper surface of bonding coat 2.In addition, on conductive layer 3, be provided with the second release sheet 5.At bonding coat 2, be arranged with the 1st release sheet 4.

Non-bonding coat 3 becomes the stratiform of extending along face direction by the granulated being formed by the 2nd silicone resin.

Shape to each particle being formed by the 2nd silicone resin is not particularly limited, such as listing roughly spherical, roughly tabular (or roughly flakey), roughly needle-like, indefinite shape (Block shape) etc.It should be noted that, in Fig. 4, depict particle as cross section roughly spherical, but its shape as mentioned above, not circumscribed.

The mean value of the maximum length of particle (referring to median size while being spherical) is for example more than 0.01 μ m, more than being preferably 1 μ m, and is for example below 100 μ m, is preferably below 50 μ m.

It is the particle of above-mentioned shape that this particle can be used preshaped, or also can be by larger particle pulverizing (comprise and pulverizing) is configured as to above-mentioned shape.Preferably by larger particle is pulverized to be configured as above-mentioned shape.

Particle does not carry out coating not expose in fact the mode of the upper surface of bonding coat 2, and particle is layered in the upper surface of bonding coat 2 with closely sealed shape.In addition a plurality of particles configuration adjacent one another are in face direction.And then though not shown in Fig. 4, particle can be overlapped on thickness direction.

The mean thickness of non-bonding coat 3 is for example more than 0.1 μ m, more than being preferably 1 μ m, and is for example below 50 μ m, is preferably below 30 μ m.The mean thickness of non-bonding coat 3 is for example calculated by observing the cross section of layer.

Then, the photosemiconductor shown in Fig. 4 is described by the manufacture method of sheet 1.

First, referring to Fig. 4, bonding coat 2 is layered on the 1st release sheet 4.

Then, non-bonding coat 3 is layered in to the upper surface of bonding coat 2.

While wanting non-bonding coat 3 to be layered in the upper surface of bonding coat 2, the particle being formed is coated on to the upper surface of bonding coat 2 by the 2nd silicone resin.Particularly, make in advance the cottons such as gauze adhere to absorbing particles, with this gauze, at the upper surface of bonding coat 2, smear.Or spread particle from bonding coat 2 tops.

Then, the 2nd release sheet 5 is layered on non-bonding coat 3.

Thus, obtain thickness direction by the 1st release sheet 4 and the 2nd release sheet 5 sheet 1 for photosemiconductor clamping, that formed by bonding coat 2 and non-bonding coat 3.

Consider that non-bonding coat 3 becomes stratiform by granulated, photosemiconductor for the sheet 1 of the photosemiconductor use sheet 1(just having manufactured except the 1st release sheet 4 and the 2nd release sheet 5) lower than the transmittance of the 1st embodiment with respect to the transmittance of the light of wavelength 500nm, transmittance with respect to the 1st embodiment, be for example below 95%, and then be below 90%, and be more than 60%.Particularly, photosemiconductor is for example more than 60%, to be preferably more than 70% with sheet 1 with respect to the transmittance of the light of wavelength 500nm, and is for example, below 99%, to be preferably below 90%.

The upper surface of sheet 1 for the photosemiconductor of just having manufactured, be non-bonding coat 3 one sides face with respect to (the nothing stretching of polypropylene (PP) sheet.Thickness 50 μ m) the peel adhesion of 25 ℃ is for example, below 0.40N/2cm, to be preferably below 0.20N/2cm, and is for example more than 0.001N/2cm.

Then, the method that optical semiconductor 8 is encapsulated to manufacture optical semiconductor device 6 as case chip with sheet 1 with this photosemiconductor is except peeling off the operation of the 1st release sheet 4, same with the 1st embodiment.

The Young's modulus of 25 ℃ of encapsulated layer 9 is for example more than 0.5MPa, more than being preferably 1MPa, and is for example, below 15MPa, to be preferably below 10MPa.

In addition, encapsulated layer 9 is for example more than 80%, to be preferably more than 90% with respect to the transmittance of the light of wavelength 500nm, and is for example, below 99.9%, to be preferably below 99%.

So, according to this sheet 1 for photosemiconductor, because non-bonding coat 3 becomes stratiform by granulated, therefore can be so that technique be simple.That is, owing to forming non-bonding coat 3 by coated particle, therefore can be so that its manufacturing process be easy.

Variation

The 2nd embodiment is as shown in the solid line of Fig. 4, at photosemiconductor with being provided with the 2nd release sheet 5 on sheet 1, and for example also can be as shown in the long and short dash line of Fig. 4, from the photosemiconductor that firm manufacture is good, with sheet 1, peel off the 2nd release sheet 5, then, to having peeled off the photosemiconductor of the 2nd release sheet 5, with sheet 1, operate (specifically preserve for a long time and/or transport).

In addition,, in the 2nd embodiment, as shown in Fig. 5 (a), make non-bonding coat 3 relative with optical semiconductor 8, and for example also can as shown in Figure 6 (a), make bonding coat 2 relative with optical semiconductor 8.

Now, first, make bonding coat 2 relative with optical semiconductor 8.

Then, as shown in Figure 6 (b), by photosemiconductor, use sheet 1 to bury (coating) optical semiconductor 8 underground.Particularly, with respect to substrate 7 sheet 1 for thermo-compressed photosemiconductor.

Thus, upper surface and the side of bonding coat 2 coatings and encapsulation optical semiconductor 8.

Obtain thus optical semiconductor device 6.

Embodiment

The numerical value of embodiment shown below etc. can be replaced into the numerical value (being higher limit or lower value) of recording in above-mentioned embodiment.

Embodiment 1

Corresponding the 1st embodiment

1. the preparation of bonding coat

According to the embodiment 1 of TOHKEMY 2012-82320 communique, at the upper surface of the 1st release sheet being formed by PET sheet, form bonding coat (referring to the downside figure of Fig. 1 (a)).

Wherein, (the 1st silicone resin, condensation reaction addition reaction curing type silicone resin combination, unreacted silicon hydrogen base are residual by the Thermocurable silicone resin on B rank for bonding coat.) with thickness 600 μ m preparations (referring to the downside figure of Fig. 1 (a)).

2. the preparation of non-bonding coat

By 75 ℃ of KR-220L(the 2nd silicone resins, poly methyl silsesquioxane, softening temperature) be dissolved in acetone and prepare solution, make solid component concentration reach 50 quality %, then, non-treated side by prepared solution coat at the 2nd release sheet being formed by PET sheet, makes the thickness after heating be about 10 μ m.

Then, will film and at 100 ℃, heat 30 minutes, remove acetone, at the upper surface of the 2nd release sheet, prepare non-bonding coat (referring to the upside figure of Fig. 1 (a)) thus.

3. the making of sheet for photosemiconductor

Then, with pressure 0.01MPa by bonding coat and non-bonding coat laminating (referring to Fig. 1 (b)).

Thus, make by the 1st release sheet and the 2nd release sheet photosemiconductor sheet clamping, that formed by bonding coat and non-bonding coat.

Embodiment 2

Corresponding the 1st embodiment

Replace KR-220L to use containing vinyl poly methyl silsesquioxane (70 ℃ of the 2nd silicone resin, softening temperatures), in addition process similarly to Example 1, make photosemiconductor sheet.

Embodiment 3

Corresponding the 2nd embodiment

1. the preparation of bonding coat

Prepare similarly to Example 1 bonding coat (referring to Fig. 4).

2. the preparation of non-bonding coat

Use mortar and pestle by 75 ℃ of KR-220L(the 2nd silicone resins, polymethyl siloxane, softening temperature) pulverize, the mean value of making maximum length is the particulate state of 10 μ m, gauze is adhered to and absorb this particle, by this gauze, at the whole face of upper surface of bonding coat, (there is no unevenly) equably the KR-220L of coated particle shape.

Thus, the upper surface at bonding coat forms non-bonding coat (referring to Fig. 4).Wherein, the mean thickness of non-bonding coat is 30 μ m.

Thus, make by the 1st release sheet and the 2nd release sheet sheet of photosemiconductor (referring to Fig. 4) clamping, that formed by bonding coat and non-bonding coat.

Embodiment 4

Corresponding the 2nd embodiment

Replace KR-220L to use containing vinyl poly methyl silsesquioxane (70 ℃ of the 2nd silicone resin, softening temperatures), in addition process similarly to Example 1, make sheet (referring to Fig. 4) for photosemiconductor.

Comparative example 1

Non-bonding coat is not set, in addition processes similarly to Example 1, make photosemiconductor sheet.

Comparative example 2

Replace KR-220L to use talcum (particulate state, spherical, median size 10 μ m), in addition process similarly to Example 3, make sheet (referring to Fig. 4) for photosemiconductor.

Evaluate

Following project is evaluated.They the results are shown in table 1.

1. transmittance

The transmittance of 1-1. initial (just manufacturing)

A. photosemiconductor sheet

Use the sheet for photosemiconductor of just having made (bonding coat and non-bonding coat) of each embodiment of spectrophotometric determination and each comparative example with respect to the transmittance of the light of wavelength 500nm, as initial total light transmittance.

Particularly, according to JIS K7361-1(1997 version) the record of " test method of the total light transmittance of plastics-transparent material ", by the spectrophotometer (U-4100, Hitachi Co., Ltd manufacture) of integrating sphere is housed, measure and peeled off the transmittance of sheet for the photosemiconductor of the 1st release sheet and the 2nd release sheet.

B. bonding coat and non-bonding coat

For the transmittance separately of the non-bonding coat of preparation in the bonding coat of preparing in embodiment 1～4 and comparative example 1,2 and embodiment 1 and 2, by measuring with above-mentioned same method.

Transmittance after 1-2. heating

By the photosemiconductor of measuring each embodiment and each comparative example with above-mentioned same method, with sheet, at 150 ℃, heat the transmittance after 3 times.

2. stripping test (peel adhesion)

The peel adhesion of sheet for 2-1. photosemiconductor

The isolated body of fitting and being formed by PP with the face of bonding coat one side of sheet at the photosemiconductor of just having made of embodiment 1～4 and comparative example 2, is processed into 2cm by their cut-outs wide, makes sample.

Then, for sample, use universal testing machine (Autograph, Shimadzu Scisakusho Ltd manufacture), the 180 degree stripping tests of implementing isolated body to peel off with the angle of 180 degree with sheet with respect to photosemiconductor.In addition, the peeling rate of isolated body is 30cm/ minute.In addition, temperature during test is 25 ℃.

In addition, for comparative example 1, at the upper surface laminating isolated body of bonding coat, in addition by implementing stripping test with above-mentioned same method.

The peel adhesion of 2-2. bonding coat

For the bonding coat of preparation in embodiment 1～4 and comparative example 1,2, by implementing 180 degree stripping tests with above-mentioned same method.

3. Young's modulus (impression meter method)

3-1. bonding coat

For the bonding coat of preparation in embodiment 1～4 and comparative example 1,2, use the Young's modulus at fixed 25 ℃ of nano impress instrumentation.

The non-bonding coat of 3-2.

For the non-bonding coat of preparation in embodiment 1 and 2, use the Young's modulus at fixed 25 ℃ of nano impress instrumentation.

Table 1

It should be noted that, although provided above-mentioned utility model as illustrated embodiment of the present utility model, this is only illustration, should not do limited explanation.Those skilled in the art variation clearly of the present utility model be included in protection domain of the present utility model.

Utilizability in industry

Photosemiconductor is the encapsulation for semiconductor element with sheet.

Claims (4)

1. a photosemiconductor sheet, is characterized in that, possesses the bonding coat being formed by the 1st silicone resin, and a non-bonding coat face, that formed by the 2nd silicone resin that is arranged at the thickness direction of described bonding coat.

2. photosemiconductor sheet according to claim 1, is characterized in that, described non-bonding coat is formed by sheet.

3. photosemiconductor sheet according to claim 1, is characterized in that, described non-bonding coat becomes stratiform by granulated.

4. an optical semiconductor device, is characterized in that, possess photosemiconductor with sheet and pass through the optical semiconductor of sheet encapsulation for described photosemiconductor,

Described photosemiconductor possesses the bonding coat being formed by the 1st silicone resin with sheet, and a non-bonding coat face, that formed by the 2nd silicone resin that is arranged at the thickness direction of described bonding coat.