JP2011187979A - Entire substrate with protecting entire member, and method of manufacturing the same - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an entire substrate with a protecting entire member allowing efficient production of an optical device, and to provide a method of manufacturing the same. <P>SOLUTION: This entire substrate with the protecting entire member, and this method of manufacturing the same includes processes of: preparing the entire substrate 33 having regions 32 formed in a lattice-like form to correspond to respective substrates 38; and arranging the protecting entire member 34 having protecting members 39 arranged to correspond the respective regions 32 on a first surface of the entire substrate 33. Each protecting member 39 is arranged to surround a chip 3 to be mounted in each of the regions 32, and has a function of reflecting light emitted from the chip 3. <P>COPYRIGHT: (C)2011,JPO&INPIT

Description

  The present invention relates to an entire substrate with an entire protective member used when manufacturing an optical device having a chip made of an optical element, and a method for manufacturing the same.

  A conventional optical device and its assembling method will be described with reference to FIG. 5 (1)-(4) are cross-sectional views showing a conventional method of assembling an optical device, and FIG. 5 (5) is a plan view showing a semi-finished product with a lens of the optical device. Here, an assembly of a light emitting diode package (LED package) will be described as an example. In addition, in order to make it easy to understand, any drawing used in the following description is schematically omitted or exaggerated as appropriate.

  In the conventional assembly method, as shown in FIG. 5A, first, the LED chip 3 is die-bonded to the upper surface 2 of the lead frame 1, and the electrodes of the lead frame 1 and the LED chip 3 are not shown. ) Is wire-bonded using the wire 4. Next, as shown in FIG. 5 (2), the cured resin is formed into a predetermined range excluding the space around the LED chip 3 and the wire 4 on the upper surface 2 and a predetermined range on the lower surface 5 by, for example, transfer molding. A protective member 6 is formed. The protection member 6 has a function of protecting the LED chip 3 and the wire 4 and, in some cases, has a function of reflecting light emitted from the LED chip 3 upward in the drawing. Further, when the protective member 6 is formed, the concave portion 7 is formed in the protective member 6 on the upper surface 2 side. The semi-finished product 8 corresponding to the LED package as one complete product is manufactured by the steps so far. In the semi-finished product 8, a portion protruding from the protective member 6 in the lead frame 1 functions as a lead of the LED package. Further, from the state shown in FIG. 5 (2), secondary molding may be performed as necessary, and the space around the LED chip 3 and the wire 4 may be filled with a translucent cured resin.

  Next, as shown in FIG. 5 (3), an adhesive (not shown) is applied to the recess 7 of the semi-finished product 8, and a translucent member made of a translucent material, that is, a lens member 9 is prepared. To do. Thereafter, the lens member 9 is held and conveyed by suction or the like, and is aligned with the concave portion 7 of the semi-finished product 8. The lens member 9 is manufactured individually by injection molding, and is composed of a translucent portion 10 having a shape made of a part of a sphere and functioning as a convex lens, and a flat flange portion 11 extending from the bottom thereof. It has a planar shape.

  Next, as shown in FIG. 5 (4), the lens member 9 is lowered and placed on the recess 7, and the adhesive is cured to bond the semi-finished product 8 and the lens member 9 of FIG. Glue. Thereby, the semi-finished product 12 with a lens shown in FIGS. 5 (4) and 5 (5) is completed. After the above steps, the lead is bent to complete the LED package.

  In addition to the above assembling methods, the following assembling methods are known depending on the structure of the LED package. As a second assembling method, a multilayer ceramic substrate was used instead of the lead frame 1, a metal cap was attached to the upper surface of the multilayer ceramic substrate instead of the protective member 6, and the top surface of the metal cap was provided. An assembly method for attaching a lens (translucent member) to a hole has been proposed (see, for example, Patent Document 1). The lens used in this method is a convex lens having a circular plane shape and a middle convex cross-sectional shape. As a third assembling method, a light-emitting diode pellet (LED chip) on a lead frame is sealed with a resin to form a photoelectric conversion element base having a square planar shape. An assembling method for mounting a transparent resin plate (translucent member) in which a flat plate portion and a convex lens portion are integrated has been proposed (for example, see Patent Document 2). This transparent resin plate with a lens is molded by an injection molding method, that is, an injection molding method.

However, according to the conventional technology described above, there are the following problems. First, in the first and second assembling methods, the lens (including the lens member in the first assembling method) has a circular planar shape and a middle convex cross-sectional shape. Thereby, even if it has a flange part of a small area, mistakes are likely to occur when handling such as picking up and transporting the lens by grasping and adsorbing. Further, since the handling jig easily comes into contact with the portion of the lens through which light is transmitted (the translucent portion 10 in FIG. 5), there is a possibility that the quality may be deteriorated by scratching this portion. Next, in any of the first to third assembling methods, since it is necessary to store, pick up, and transport the lens in the state of individual pieces, management of inventory and the process are complicated. Next, in any of the first to third assembling methods, it is necessary to manufacture the lens and the semi-finished product in units of one unit and to attach one lens to each semi-finished product. It is difficult to improve production efficiency when producing
JP 2003-163382 A (page 3, FIG. 1, FIG. 2, FIG. 4) Japanese Patent Laid-Open No. 4-348088 (page 2 to page 3, FIGS. 1 to 3)

  The problem to be solved by the present invention is that it is difficult to improve the production efficiency when assembling an optical device, and the quality may be lowered.

  In order to solve the above-described problems, an entire substrate with a protective whole member according to the present invention is a substrate (38) and a chip (3) that is mounted on a first surface of the substrate (38) and includes an optical element. And an optical device (37) provided with a translucent sealing member (25) provided on the first surface for the purpose of sealing the chip (3). An overall substrate (33) with a protective overall member, having an area (32) formed in a lattice shape so as to correspond to each of the substrates (38), and an area (32) A protection member (39) having a protection member (34) having a protection member (39) provided so as to surround the chip (3) to be mounted on the first surface of each. Has the function of reflecting the light emitted from the chip (3). And butterflies.

  An entire substrate with a protective whole member according to the present invention comprises a substrate (38), a chip (3) made of an optical element mounted on a first surface of the substrate (38), and the chip (3). Whole substrate with protective whole member used when manufacturing an optical device (37) provided with a translucent sealing member (25) provided on the first surface for the purpose of sealing (33), an entire substrate (33) having regions (32) formed in a lattice shape so as to correspond to the substrate (38), and a chip (3) mounted on each of the regions (32) And an overall protection member (34) having a protection member (39) provided so as to surround the chip (3) in each of the regions (32), and the protection member (39) It has a function of reflecting light emitted from the chip (3). That.

  Moreover, the whole board | substrate with the whole member for protection which concerns on this invention has a chip | tip (3) and a board | substrate (38) in each of the area | region (32) in the whole board | substrate (33) with the whole member for protection mentioned above. The electrodes are connected to each other inside the protective member (39) in a plan view.

  Moreover, the whole board | substrate with the whole member for protection which concerns on this invention has a chip | tip (3) and a board | substrate (38) in each of the area | region (32) in the whole board | substrate (33) with the whole member for protection mentioned above. The electrodes are connected using wire bonding or flip chip bonding.

  Moreover, the whole board | substrate with the whole member for protection based on this invention is the above-mentioned whole board | substrate with a whole member for protection (33), and the upper surface of a chip | tip (3) in each area | region (32) is a member for protection (39 ) Is lower than the upper surface.

  Moreover, the whole board | substrate with the whole member for protection which concerns on this invention is the whole board | substrate (33) with the whole member for protection mentioned above, A board | substrate (38) cut | disconnects the whole board | substrate (33) in a grid | lattice form. It corresponds to the part formed by.

  Moreover, the whole board | substrate with the whole member for protection which concerns on this invention is the whole board | substrate (33) with the whole member for protection mentioned above, The whole member for protection (34) was formed by transfer molding, It is characterized by the above-mentioned. .

  Moreover, the whole board | substrate with the whole member for protection based on this invention WHEREIN: The whole board | substrate for protection (34) was formed by compression molding in the whole board | substrate (33) with the whole member for protection mentioned above. .

  Moreover, the whole board | substrate with the whole member for protection which concerns on this invention is the whole board | substrate (33) with the whole member for protection mentioned above, and the whole member for protection (34) in a 1st surface is shape | molded integrally previously. It is characterized by being formed by adhering the entire protective member (34) to the first surface.

  In addition, the method of manufacturing an entire substrate with a protective whole member according to the present invention includes a substrate (38), a chip (3) made of an optical element mounted on a first surface of the substrate (38), The whole for protection used when manufacturing the optical device (37) provided with the translucent sealing member (25) provided in the 1st surface for the purpose of sealing chip | tip (3). A method of manufacturing an entire substrate (33) with members, comprising: preparing an entire substrate (33) having regions (32) formed in a lattice shape so as to correspond to the substrate (38), and the entire substrate And a step of providing an overall protection member (34) having a protection member (39) provided corresponding to each of the regions (32) on the first surface in (33), and a protection member (39 ) Is the tip (3) to be mounted in each of the regions (32) Each is provided so as to surround the, and having a function of reflecting light emitted from the chip (3).

  In addition, the method of manufacturing an entire substrate with a protective whole member according to the present invention includes a substrate (38), a chip (3) made of an optical element mounted on a first surface of the substrate (38), The whole for protection used when manufacturing the optical device (37) provided with the translucent sealing member (25) provided in the 1st surface for the purpose of sealing chip | tip (3). A method for manufacturing an entire substrate (33) with a member, comprising: preparing an entire substrate (33) having regions (32) formed in a lattice shape so as to correspond to the substrate (38); 32) attaching the chip (3) to each of the above, and the entire protective substrate having a protective member (39) provided corresponding to each of the regions (32) on the first surface of the entire substrate (33). Providing a member (34), and the protective member (39) Each is provided so as to surround the frequency chip mounted in each of (32) (3), and having a function of reflecting light emitted from the chip (3).

  Moreover, the manufacturing method of the whole board | substrate with the whole member for protection which concerns on this invention is a chip | tip (3) and board | substrate in each of the area | region (32) in the manufacturing method of the whole board | substrate (33) with the whole member for protection mentioned above. The electrodes of (38) are connected to each other inside the protective member (39) in plan view.

  Moreover, the manufacturing method of the whole board | substrate with the whole member for protection which concerns on this invention is a chip | tip (3) and board | substrate in each of the area | region (32) in the manufacturing method of the whole board | substrate (33) with the whole member for protection mentioned above. (38) are connected to each other using wire bonding or flip chip bonding.

  Moreover, the manufacturing method of the whole board | substrate with the whole member for protection based on this invention is a manufacturing method of the whole board | substrate (33) with the whole member for protection mentioned above, The upper surface of a chip | tip (3) in each area | region (32). Is lower than the upper surface of the protective member (39).

  Further, the manufacturing method of the whole substrate with the protective whole member according to the present invention is the above-described method of manufacturing the whole substrate (33) with the whole protective member, wherein the substrate (38) lattices the whole substrate (33). It corresponds to a portion formed by cutting into a shape.

  In addition, the method for manufacturing the whole substrate with the protective whole member according to the present invention includes the step of providing the whole protective member (34) in the method for producing the whole substrate (33) with the whole protective member. The protective whole member (34) is formed in a lump by molding.

  Moreover, the manufacturing method of the whole board | substrate with the whole member for protection which concerns on this invention is compression in the process of providing the whole board | substrate for protection (34) in the manufacturing method of the whole board | substrate with a whole member for protection (33) mentioned above. The protective whole member (34) is formed in a lump by molding.

  Moreover, the manufacturing method of the whole board | substrate with the whole member for protection based on this invention WHEREIN: In the manufacturing method of the whole board | substrate (33) with the whole member for protection mentioned above, in the process of providing the whole member for protection (34), The protective whole member (34) formed integrally is bonded to the first surface.

  According to the present invention, the entire substrate (33) with the entire protective member can be manufactured by providing the entire protective substrate (34) on the entire substrate (33).

  A substrate (38), a chip (3) made of an optical element mounted on the first surface of the substrate (38), and a transparent member provided on the first surface for sealing the chip (3). A method for producing an entire substrate (33) with a protective whole member used when producing an optical device (37) comprising a sealing member (25) having optical properties, the substrate (38) And a step of preparing an entire substrate (33) having regions (32) formed in a lattice shape so as to correspond to each of the regions, and a first surface of the entire substrate (33) corresponding to each of the regions (32). Providing a protective overall member (34) having a protective member (39) provided. The protection member (39) is provided so as to surround the chip (3) to be mounted in each of the regions (32), and has a function of reflecting light emitted from the chip (3).

Reference example 1

  Reference Example 1 of the present invention will be described with reference to FIGS. 1 (1) to 1 (4) are partial cross-sectional views showing an optical device assembling method according to this reference example in the order of steps, and FIG. 1 (5) is a perspective view showing a completed lens member. In any of the drawings shown below, the same components as those shown in FIG. 5 are denoted by the same reference numerals and description thereof is omitted. In the following description, an LED chip will be described as an example of an optical element, and an LED package will be described as an example of an optical device. The present invention can be applied not only to an LED chip but also to a light receiving element that converts received light into an electrical signal, for example, a chip such as a photodiode (PD) or a solid-state imaging element. In addition, the present invention can be applied to a light emitting element that emits light in accordance with the received electrical signal, for example, a chip such as a laser diode (LD). In addition, the present invention can be applied to modules used for optical communication. That is, the present invention can be applied to optical elements.

  In this reference example, a lens member that adheres to a semi-finished product (see the semi-finished product 8 in FIG. 5 (3)) having a substrate, an LED chip, and a protective member, that is, a translucent member, is formed including a plurality of lens members. It is characterized in that the molded body is formed by separating the molded body after resin molding at once. According to the method for assembling an optical device according to the present reference example, first, as shown in FIG. Then, a predetermined amount of granular resin material 16 made of a thermosetting resin having translucency is supplied. A plurality of concave portions corresponding to the shape of the lens member is formed in the cavity 15 in a lattice shape. Further, the resin material 16 may be in the form of powder, lump, or sheet in addition to the illustrated granular shape, and a thermoplastic resin having a certain translucency may be used. Further, a resin material that is liquid at normal temperature may be injected into the cavity 15.

  Next, as shown in FIG. 1 (2), the upper mold 14 is lowered from the state of FIG. 1 (1), the lower mold 13 and the upper mold 14 are clamped, and the resin material 16 is pressed. Then, the resin material 16 is heated and melted using heaters (not shown) provided in the lower mold 13 and the upper mold 14 to generate the fluid resin 17 in the cavity 15. Thereafter, the fluid resin 17 is cured to form a molded body 19 made of the cured resin 18 as shown in FIG. Thereby, the molded object 19 was shape | molded collectively using what is called compression molding. Here, the molded body 19 can also be molded collectively using transfer molding.

  Next, as shown in FIG. 1 (3), the upper die 14 is raised to open the lower die 13 and the upper die 14. And after taking out the molded object 19, it hold | maintains the molded object 19 using means, such as adsorption | suction, and conveys it to the cutting device used at the next process.

  Next, as shown in FIG. 1 (4), the molded body 19 is temporarily fixed to the stage 21 using a dicing sheet 20 having appropriate tackiness, in other words, weak adhesive force. Then, using the rotary blade 22, along the virtual dicing line 23 provided on the molded body 19, molding is performed in the Y direction (front-rear direction in the figure) and the X direction (left-right direction in the figure). The body 19 is cut. As a result, the molded body 19 is separated into pieces, and the translucent member shown in FIG. 1 (5), that is, the translucent part 10 functioning as a convex lens, and the flat flange part 24 having a rectangular planar shape. The lens member 25 having the above is completed. The lens member 25 having the rectangular planar shape corresponds to the translucent member according to the present invention. Here, after the molded body 19 is cut to form all the lens members 25, all the lens members 25 are temporarily fixed to the dicing sheet 20, and are transported, stored, shipped, and the like.

  Next, an adhesive (not shown) is applied to the concave portion 7 of the semi-finished product 8 in the same manner as in FIG. Thereafter, the lens member 25 is held by suction or the like, and further separated and conveyed from the dicing sheet 20 to be aligned with the concave portion 7. In this reference example, the concave portion 7 shown in FIG. 5 has a rectangular planar shape corresponding to the flange portion 24 of FIG.

  Next, as in FIG. 5 (4), the lens member 25 is lowered and placed on the recess 7, and the adhesive is cured. Thereby, the semi-finished product with lens (see the semi-finished product 12 with lens in FIGS. 5 (4) and (5)) is completed. The lead device is bent after the above steps to complete the optical device (LED package) according to this reference example.

  As described above, according to the present reference example, the molded body 19 formed in one batch is individually provided for the optical device in which the lead frame is provided with the protective member and the lens member 25 fixed to the top surface. A lens member 25 formed by being separated into pieces is used. Therefore, compared to the case where the lens members are individually formed by injection molding or the like, the production efficiency is improved when the optical device is produced, and inventory management, storage, transportation, and the like are simplified. The lens member 25 has a flat and wide flange portion 24 and a rectangular planar shape. Thereby, when the lens member 25 is handled, the flange portion 24 can be grasped or attracted to the flange portion 24. Even if the area of the flange portion 24 is small, the lens member 25 can be held by sandwiching the side surface at each side. Therefore, when the lens member 25 is handled, occurrence of mistakes and deterioration of quality due to scratches on the light transmitting portion 10 are suppressed.

  In this reference example, the molded body 19 was cut using the rotary blade 22. Not limited to this, when forming the molded body 19, a groove is formed at the position of the dicing line 23, and the molded body 19 is separated into individual lens members 25 by being bent at the groove portion and separated from each other. Also good.

  Further, the lens member 25 has been described as an example of the translucent member according to the present invention. The translucent member according to the present invention is not limited to this, and the lens member integrated with the lens barrel (the portion formed of the protective member 6 and the lens member 9 on the upper side of the substrate 1 in FIG. 5 (3)). It is good.

Reference example 2

  Reference Example 2 of the present invention will be described with reference to FIGS. 2 (1) to 2 (4) are partial cross-sectional views showing the assembling method of the optical device according to this reference example in the order of steps, and FIG. 2 (5) is a plan view showing a semi-finished product with a lens of the optical device. In this reference example, when the molded body is cut, the molded body is temporarily fixed to the stage, and the lens member separated by cutting the molded body is bonded to the semi-finished product with a lens. Is performed by one double-sided adhesive sheet. According to this reference example, first, as shown in FIG. 2 (1), the double-sided adhesive sheet 26 having a three-layer structure is attached to the lower surface of the molded body 19. The double-sided adhesive sheet 26 includes a base material 27, a temporary fixing temporary adhesive layer 28 that is formed on one surface (lower surface in the drawing) and has a weak adhesive force, and the other surface of the base material 27 ( It is composed of a main fixing layer 29 for fixing that is formed on the upper surface in the drawing and has a strong adhesive force. Then, the main adhesive layer 29 of the double-sided adhesive sheet 26 is attached to the lower surface of the molded body 19. Further, the main adhesive layer 29 corresponding to one lens member 25 is provided in a frame shape so as to exist below the flange portion 24 and not below the light transmitting portion 10. For example, when a transparent material such as acrylic is used as the main adhesive layer 29, the main adhesive layer 29 may be provided on the entire lower surface of the lens member 25.

  Next, instead of the dicing sheet 20 shown in FIG. 1 (4), the double-sided adhesive sheet 26 is used, and the molded body 19 is temporarily fixed to the stage 21 by the temporary adhesive layer 28. Then, the molded body 19 is cut along the dicing line 23 using the rotary blade 22.

  Next, the lens member 25 separated by cutting is peeled off from the temporary adhesive layer 28 on the stage 21. Thereby, as shown in FIG. 2B, the lens member 25 is formed in which the main adhesive layer 29 and the base material 27 are adhered to the lower surface in this order.

  Next, as shown in FIG. 2 (3), the lens member 25 is held and transported by sucking the flange portion 24 using the suction holder 30. Then, as shown in FIG. 2 (4), the lens member 25 is aligned with the semi-finished product 31, lowered, brought into contact with the upper surface of the semi-finished product 31, and further pressurized. Thereby, the lens member 25 is bonded to the upper surface of the semi-finished product 31. Thereafter, lead bending is performed to complete the optical device (LED package) according to this reference example.

  As described above, according to this reference example, the temporary fixing means used when cutting the molded body 19 into pieces and the permanent fixing means for bonding the separated lens member 25 to the semi-finished product 31. As an example, one double-sided adhesive sheet 26 is used. Thereby, since the process of apply | coating an adhesive agent to the semi-finished product 31 can be abbreviate | omitted, the production efficiency at the time of producing an optical device can be improved.

  A first embodiment of the present invention will be described with reference to FIG. 3 (1)-(4) are partial cross-sectional views showing the optical device assembling method according to this embodiment in the order of steps, and FIG. 3 (5) is a cross-sectional view showing the completed optical device. According to the method for assembling an optical device according to the present embodiment, first, as shown in FIG. 3 (1), an entire substrate 33 made of a printed circuit board or the like in which regions 32 corresponding to the optical device are formed in a lattice shape is prepared. To do. Then, the chip 3 is mounted on each region 32 having a rectangular planar shape, and wire bonding is performed using the wire 4.

  Next, as shown in FIG. 3B, the entire protective member 34 that surrounds the chip 3 in each region 32 is formed by batch transfer molding. Further, in this step, the entire protective member independently and integrally formed independently of the entire substrate 33 may be aligned and bonded to the entire substrate 33. By these methods, the protective whole member 34 can be provided collectively on the whole substrate 33.

  Next, as shown in FIG. 3 (3), a molded body 19 formed in a lump using a translucent resin is prepared (see FIG. 1 (3)). An adhesive sheet 35 is preferably pasted on the lower surface of the molded body 19 in advance. The adhesive sheet 35 has the same function as the main adhesive layer 29 shown in FIG. Then, after positioning the molded body 19 with respect to the entire substrate 33, the molded body 19 is lowered and pressed against the top surface (upper surface in the drawing) of the protective overall member 34. As a result, the molded body 19 and the protective overall member 34 are bonded together.

  Next, as shown in FIG. 3 (4), an intermediate body 36 formed by bonding the molded body 19 and the protective whole member 34 is temporarily fixed to a stage (not shown). Then, using the rotary blade 22, along the dicing line 23 virtually provided in the intermediate body 36, it is intermediate between the Y direction (front-rear direction in the figure) and the X direction (left-right direction in the figure). Cut the body 36. Thereby, the intermediate body 36 is separated into individual regions 32 and separated into individual pieces.

  Through the steps up to here, the optical device 37 (LED package) according to the present embodiment shown in FIG. This optical device 37 includes a substrate 38 in which the entire substrate 33 is separated, a chip 3 mounted on the upper surface of the substrate 38, a protection member 39 provided so as to surround the chip 3, and a protection member. And a lens member 25 which is a translucent member bonded to the upper surface of 39. The optical device 37 is electrically connected to another printed circuit board or the like (not shown) by an external electrode (not shown) provided on the lower surface of the substrate 38.

  As described above, according to the present embodiment, the protective whole member 34 surrounding the chip 3 attached to each region 32 of the whole substrate 33 is formed in a lump and is formed in a lump and has translucency. The molded body 19 is bonded onto the protective overall member 34 to form an intermediate body 36, and the intermediate body 36 is separated into units of each region 32 to complete the optical device 37. Therefore, the production efficiency of the optical device is greatly improved as compared with the assembly method (see FIG. 5) in which the lens member is bonded to each semi-finished product. Further, the lens member 25 included in the optical device 37 is integrally handled as the molded body 19 until the intermediate body is cut. Thus, the molded body 19 can be gripped or adsorbed using a portion (peripheral portion) that does not correspond to the lens member 25 in the molded body 19. Therefore, when the molded body 19 is handled, it is possible to prevent occurrence of mistakes and quality deterioration due to scratches on the lens member 25. Moreover, since the optical device 37 has a rectangular planar shape, handling of the optical device 37 is facilitated by sandwiching the side surface, and damage to the lens member 25 can be prevented.

  A second embodiment of the present invention will be described with reference to FIG. 4 (1) to 4 (4) are partial cross-sectional views showing the optical device assembling method according to this embodiment in the order of steps, and FIG. 4 (5) is a cross-sectional view showing the completed optical device. According to the optical device assembling method according to the present embodiment, first, as in the case shown in FIG. 3 (1), the chip 3 is mounted on each region 32 of the entire substrate 33, and wire bonding is performed using the wires 4. I do. And the lower mold | type 40 and the upper mold | type 41 which oppose each other are prepared. Here, a cavity 42 is formed in the lower mold 40, and a plurality of recesses corresponding to the respective chips 3 are formed in a lattice shape in the cavity 42. Then, as shown in FIG. 4A, the entire substrate 33 is fixed to the upper mold 41 by a method such as suction. In addition, as in the case shown in FIG. 1A, a predetermined amount of granular resin material 43 made of a thermosetting resin having translucency is supplied to the cavity 42.

  Next, as shown in FIG. 4 (2), the resin material 43 is heated and melted to produce a fluid resin 44 in the cavity 42, and the lower mold 40 and the upper mold 41 are clamped. Here, in order to heat the resin material 43, a heater (not shown) provided in the lower mold 40 is used. Further, instead of or in addition to the heater, a contact type heating plate or a non-contact type halogen lamp inserted between the lower mold 40 and the upper mold 41 may be used.

  Next, as shown in FIG. 4 (3), the fluid resin 44 is cured to form a molded body 45 made of a cured resin, and an intermediate body 46 having the entire substrate 33 and the molded body 45 is formed. Then, the upper mold 41 is raised to open the lower mold (not shown) and the upper mold 41. The molded body 45 functions as an entire sealing member that collectively seals the chips 3 on the entire substrate 33. Through the steps so far, the intermediate body 46 is formed in a lump using compression molding. It should be noted that transfer molding may be used instead of compression molding to form the cured resin and simultaneously mold the intermediate body 46.

  Next, as shown in FIG. 4 (4), the intermediate body 46 is temporarily fixed to a stage (not shown). And using the rotary blade 22, along the dicing line 23 virtually provided in the intermediate body 46, it is intermediate in the Y direction (front-rear direction in the figure) and the X direction (left-right direction in the figure). Cut the body 46. Thereby, the intermediate body 46 is separated into individual regions 32 and separated into individual pieces.

  Through the steps so far, the optical device 47 (LED package) according to the present embodiment shown in FIG. The optical device 47 includes a substrate 38 in which the entire substrate 33 is separated, a chip (not shown) mounted on the upper surface of the substrate 38, a convex lens-shaped light transmitting portion 48, and a flat flange portion 49. In addition, a translucent member for sealing the chip, that is, a lens member 50 is provided.

  As described above, according to the present embodiment, the chips 3 attached to the respective regions 32 of the entire substrate 33 are collectively sealed to form the intermediate body 46, and the intermediate body 46 is divided into units of each region 32. Thus, the optical device 47 is completed. Thereby, the production efficiency of the optical device is further greatly improved as compared with the assembly method (see FIG. 5) in which the lens member is bonded to each semi-finished product. Further, the production efficiency is improved as compared with the assembling method (see FIG. 3) for forming the protective member. In addition, the intermediate body 46 can be gripped or adsorbed by using a portion of the intermediate body 46 that does not correspond to the lens member 50 (a peripheral portion of the molded body 45). Therefore, when the intermediate body 46 is handled, it is possible to prevent the occurrence of mistakes and the deterioration of quality due to the lens member 50 being damaged. In addition, since the optical device 47 has a rectangular planar shape, handling of the optical device 47 is facilitated by sandwiching the side surface, and damage to the lens member 50 can be prevented.

  In this embodiment, the intermediate body 46 having the entire substrate 33 and the molded body 45 made of a cured resin is molded in a lump. Instead of this, a member that replaces the portion made of the cured resin may be integrally formed in advance using a translucent resin, and the formed member may be used as the entire sealing member. In this case, first, the whole sealing member is integrally formed in advance independently and independently of the whole substrate 33. Specifically, a portion of the molded body 45 excluding a predetermined space around the LED chip 3 and the wire 4, in other words, the molded body 19 shown in FIG. Corresponding portions are collectively formed as a whole sealing member. Next, the whole sealing member is aligned and bonded to the whole substrate 33. Thereby, the whole member for sealing which functions as a protection member and a lens member can be collectively provided on the whole substrate 33, and an intermediate can be formed. Next, the intermediate is separated into 32 units for each region and separated into individual pieces. The optical device thus obtained has a configuration in which the lens member 25 and the protection member 39 shown in FIG. 3 (5) are integrated and made of a translucent resin.

  In Reference Examples 1 and 2 and Examples 1 and 2, the lens members 25 and 50 have convex lens-like light transmitting portions 10 and 48 and flat flange portions 24 and 49. However, the present invention is not limited to this, and the entire lens members 25 and 50 may be formed so as to form a convex lens-like light transmitting portion. In this case, the dicing sheet (see the dicing sheet 20 in FIG. 1 (4)) is expanded after cutting, and the side surfaces of the lens members 25 and 50 or the side surfaces of the optical devices 37 and 47, that is, the convex lens-like light transmission. You can grab parts other than the part. Thereby, when handling the lens members 25 and 50 and the optical devices 37 and 47, respectively, it is possible to prevent occurrence of mistakes and deterioration of quality.

  Further, wire bonding was used for electrical connection between electrodes of the chip and the substrate. Alternatively, other connection methods may be used. For example, the chip may be flip-chip bonded so as to emit or receive light through an opening provided in the substrate.

  Moreover, the molded object 19 and the intermediate bodies 36 and 46 were each cut | disconnected using the rotary blade 22. FIG. However, the present invention is not limited to this, and laser cutting (melting), cutting with a wire saw or the like may be used.

  Further, the lens member 25 is arranged so as to be convex toward the outside of the optical device. Not limited to this, the lens member 25 may be arranged so as to be convex on the inner side of the optical device. In addition, the lens member 25 may have a shape that is convex on both sides, or may have a shape having a convex lens-shaped light transmitting portion and a light reflecting wall provided around the convex portion. About these points, it is the same also in the molded object 19 of Example 1, and the whole member for sealing in the writing of Example 2.

  Further, for example, when a lens member is not required as in a certain type of light receiving element or the like, a flat plate member may be used as the translucent member. Alternatively, a flat molded body may be molded in a lump and bonded to the entire protective member to form an intermediate body, and then the intermediate body may be separated to complete an individual optical device (see FIG. 3 (3), (4)). Furthermore, it is good also as replacing with the lens member 50 shown by FIG. 4 and having a flat member. In these cases, the flat plate member corresponds to the translucent member according to the present invention.

  The present invention can also be applied when the optical device has a light receiving element or when the optical device has both a light emitting element and a light receiving element.

  Further, the present invention is not limited to the above-described first and second embodiments, and can be arbitrarily combined, changed, or selected as necessary within the scope not departing from the gist of the present invention. Can be adopted.

1 (1)-(4) are partial cross-sectional views showing the optical device assembling method according to Reference Example 1 in the order of steps, and FIG. 1 (5) is a perspective view showing a completed lens member. 2 (1) to 2 (4) are partial cross-sectional views showing an optical device assembling method according to Reference Example 2 in the order of steps, and FIG. 2 (5) is a plan view showing a semi-finished product with a lens of the optical device. 3 (1) to 3 (4) are partial cross-sectional views illustrating the optical device assembling method according to the first embodiment in the order of steps, and FIG. 3 (5) is a cross-sectional view illustrating the completed optical device. 4 (1) to 4 (4) are partial cross-sectional views illustrating the optical device assembling method according to the second embodiment in the order of steps, and FIG. 4 (5) is a cross-sectional view illustrating the completed optical device. 5 (1)-(4) are cross-sectional views showing a conventional method of assembling an optical device, and FIG. 5 (5) is a plan view showing a semi-finished product with a lens of the optical device.

1 Lead frame (substrate)
2 Upper surface 3 LED chip (chip)
4 Wire 5 Lower surface 6, 39 Protection member 7 Recessed portion 8, 31 Semi-finished product 9 Lens member 10 Translucent portion 11, 24, 49 Flange portion 12 Semi-finished product with lens 13, 40 Lower die 14, 41 Upper die 15, 42 Cavity 16, 43 Resin material 17, 44 Fluid resin 18 Cured resin 19 Molded body 20 Dicing sheet 21 Stage 22 Rotary blade 23 Dicing line 25, 50 Lens member (sealing member)
26 Double-sided adhesive sheet 27 Base material 28 Temporary adhesive layer 29 Main adhesive layer 30 Adsorption holder 32 Region 33 Overall substrate 34 Overall member for protection 35 Adhesive sheet 36, 46 Intermediate 37, 47 Optical device 38 Substrate 45 Molded body 48 Translucent body Part

Claims (18)

A substrate, a chip made of an optical element mounted on a first surface of the substrate, and a light-transmitting sealing member provided on the first surface for the purpose of sealing the chip. An overall substrate with a protective overall member used when manufacturing an optical device,
An entire substrate having regions formed in a lattice shape so as to correspond to each of the substrates;
A protective overall member having a protective member provided so as to surround the chip to be mounted on the first surface in each of the regions;
The protective substrate has a function of reflecting light emitted from the chip, and is a whole substrate with a protective whole member. A substrate, a chip made of an optical element mounted on a first surface of the substrate, and a light-transmitting sealing member provided on the first surface for the purpose of sealing the chip. An overall substrate with a protective overall member used when manufacturing an optical device,
An entire substrate having regions formed in a lattice shape so as to correspond to each of the substrates;
The chip mounted in each of the regions;
A protective overall member having a protective member provided so as to surround the chip in each of the regions;
The protective substrate has a function of reflecting light emitted from the chip, and is a whole substrate with a protective whole member. In the whole board | substrate with the whole member for protection described in Claim 1 or 2,
An overall substrate with an overall protective member, wherein the electrodes of the chip and the substrate in each of the regions are connected to each other inside the protective member in plan view. In the whole board | substrate with the whole member for protection described in Claim 1 or 2,
An overall substrate with a protective overall member, wherein the electrodes of the chip and the substrate in each of the regions are connected to each other using wire bonding or flip chip bonding. In the whole board | substrate with the whole member for protection described in Claim 1 or 2,
An overall substrate with a protective overall member, wherein the upper surface of the chip is lower than the upper surface of the protective member in each of the regions. In the whole board | substrate with the whole member for protection described in any one of Claims 1-5,
The whole substrate with a whole member for protection characterized in that the substrate corresponds to a portion formed by cutting the whole substrate into a lattice shape. In the whole board | substrate with the whole member for protection described in any one of Claims 1-5,
An overall substrate with an overall protective member, wherein the overall protective member is formed by transfer molding. In the whole board | substrate with the whole member for protection described in any one of Claims 1-5,
An overall substrate with an overall protective member, wherein the overall protective member is formed by compression molding. In the whole board | substrate with the whole member for protection described in any one of Claims 1-5,
The protective whole member on the first surface is formed by adhering the protective whole member integrally molded in advance to the first surface. Whole board. A substrate, a chip made of an optical element mounted on a first surface of the substrate, and a light-transmitting sealing member provided on the first surface for the purpose of sealing the chip. A method of manufacturing an entire substrate with a protective whole member used when manufacturing an optical device,
Preparing an entire substrate having a region formed in a lattice shape so as to correspond to each of the substrates;
Providing a protective overall member having a protective member provided corresponding to each of the regions on the first surface of the overall substrate, and
The protective member is provided so as to surround the chip to be mounted in each of the regions, and has a function of reflecting light emitted from the chip. Manufacturing method of the entire board. A substrate, a chip made of an optical element mounted on a first surface of the substrate, and a light-transmitting sealing member provided on the first surface for the purpose of sealing the chip. A method of manufacturing an entire substrate with a protective whole member used when manufacturing an optical device,
Preparing an entire substrate having a region formed in a lattice shape so as to correspond to each of the substrates;
Attaching the chip to each of the regions;
Providing a protective overall member having a protective member provided corresponding to each of the regions on the first surface of the overall substrate, and
The protective member is provided so as to surround the chip mounted in each of the regions, and has a function of reflecting light emitted from the chip, and the whole with a protective whole member A method for manufacturing a substrate. In the manufacturing method of the whole board | substrate with the whole member for protection described in Claim 10 or 11,
A method of manufacturing an entire substrate with an entire protective member, wherein electrodes of the chip and the substrate in each of the regions are connected to each other inside the protective member in plan view. In the manufacturing method of the whole board | substrate with the whole member for protection described in Claim 10 or 11,
A method of manufacturing an entire substrate with a protective whole member, wherein electrodes of the chip and the substrate in each of the regions are connected using wire bonding or flip chip bonding. In the manufacturing method of the whole board | substrate with the whole member for protection described in Claim 10 or 11,
A method for manufacturing an entire substrate with an entire protecting member, wherein the upper surface of the chip is located lower than the upper surface of the protecting member in each of the regions. In the manufacturing method of the whole board | substrate with the whole member for protection described in any one of Claims 10-14,
The method of manufacturing a whole substrate with a protective whole member, wherein the substrate corresponds to a portion formed by cutting the whole substrate into a lattice shape. In the manufacturing method of the whole board | substrate with the whole member for protection described in any one of Claims 10-15,
In the step of providing the whole protecting member, the whole protecting member is formed in a lump by transfer molding, and the method for producing the whole substrate with the whole protecting member. In the manufacturing method of the whole board | substrate with the whole member for protection described in any one of Claims 10-15,
In the step of providing the whole protecting member, the whole protecting member is formed in a lump by compression molding, and the method of manufacturing the whole substrate with the whole protecting member. In the manufacturing method of the whole board | substrate with the whole member for protection described in any one of Claims 10-15,
In the step of providing the whole protecting member, the whole protecting member formed integrally in advance is bonded to the first surface. The method for manufacturing the whole substrate with the whole protecting member.

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