JP2004319900A - Mold for method for sealing with resin and method for deciding specification of the same - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a mold for sealing with a resin having a size and a shape in which the fault of a contact hardly occurs when a chip is sealed with the resin by the MAP system. <P>SOLUTION: On an upper mold 1 of a mold for sealing with the resin used when the respective chips 16 mounted on the respective regions of a substrate 3 are collectively sealed with the resin, a cull 6 for storing the molten resin, a cavity 8 for dispensing the molten resin, a resin flow channel 7 for communicating with the cull 6 and the cavity 8, an air vent 9 for communicating with the cavity 8 and the outside of the mold for sealing with the resin, a resin flow channel member 10 provided with the resin flow channel 7 and fitted to the upper mold 1, and an air vent member 11 provided with the air vent 9 and fitted to the upper mold 1, are provided. The resin flow channel member 10 and the air vent member 11 are respectively exchangeable and those specifications are decided according to the substrate 3 and the chip 16. Thus, the mold for sealing with the resin having the resin flow channel 7 and the air vent 9 of optimal specification can be completed according to the substrate 3 and the chip 16. <P>COPYRIGHT: (C)2005,JPO&NCIPI

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to a resin-sealing mold and a method for determining specifications of a resin-sealing mold used when a plurality of electronic components mounted on a substrate are collectively resin-sealed.
[0002]
[Prior art]
Conventionally, in order to manufacture a package as a product, a chip-shaped electronic component (hereinafter, referred to as “chip”) mounted on a lead frame, a printed board, or the like (hereinafter, referred to as “substrate”) is resin-sealed. A transfer molding method using a mold is widely used. In this transfer molding method, a chip mounted on a substrate is housed in a cavity of a mold, a molten resin is injected into the cavity while the mold is clamped, the resin is cured, and after the mold is opened, a molded product is taken out. Things. Here, the size and shape of the resin flow path for injecting the molten resin into the cavity, that is, the specifications, affect the quality of the molded product. In addition, since voids (bubbles) occur in a molded product, which causes a defect, an air vent may be provided in a mold for the purpose of preventing voids (for example, see Patent Document 1). The size and shape of the air vent, that is, specifications, also affect the quality of the molded product. Such a resin molding die in the transfer molding method is also used in a method called MAP (Molded Array Packaging) for resin-encapsulating a plurality of chips at once, which has been adopted in recent years due to a demand for improvement in productivity. (For example, see Non-Patent Document 1). This MAP method uses a so-called multi-cavity substrate divided into a grid-like area, mounts and wires chips in each area, and then collectively seals the resin with each other. This is a method of cutting individual products to complete individual packages.
[0003]
[Patent Document 1]
JP-A-3-51111 (page 1-2, FIG. 1)
[Non-patent document 1]
Kiyasu Kawai, 1 other, "Assembly Tape for QFN", Hitachi Chemical Technical Report, Hitachi Chemical Co., Ltd., July 2002, No. 39, p. 17-18
[0004]
[Problems to be solved by the invention]
By the way, when resin sealing is performed using the above-described conventional technology, there are the following problems. That is, depending on the type of the substrate and the chip, there is a possibility that the wire used for wiring the electrodes of the chip and the substrate may be broken or deformed, and defects such as voids may occur in the molded product after sealing. If a defect occurs, it is necessary to examine the dimensions and shape of the resin flow path of the mold or the air vent, that is, the specifications, depending on the situation of the defect, and redesign and remanufacture the mold. And disadvantages in terms of lead time.
[0005]
In particular, for a substrate used in the MAP method, the size of each region corresponding to an individual package on the substrate may be different even if the size and shape of the cavity accommodating a plurality of chips and the substrate are the same. . Further, even when the size of each region of the substrate is the same, the size of the chip accommodated in each region and the number, length, layout, etc. of the wires connecting the electrodes of the chip and the substrate are often different. . Therefore, when the size and shape of the cavity and the substrate are the same, resin sealing can be performed without any problem when using a substrate and chip of a certain model, but when using a substrate and chip of another model, it is defective. Is likely to occur.
[0006]
The present invention has been made in order to solve the above-mentioned problems, and when a chip is resin-sealed by the MAP method, a resin-sealing mold having a size and shape in which a defect is unlikely to occur, in other words, a defect An object of the present invention is to provide a resin-sealing mold having specifications that are unlikely to occur, and a method for determining the specifications of the resin-sealing mold that can easily determine such specifications.
[0007]
[Means for Solving the Problems]
In order to solve the above-mentioned technical problems, the resin sealing mold according to the present invention is used when collectively sealing electronic components mounted on each region of the substrate with resin, and the molten resin is stored therein. And a cavity into which the molten resin is injected, and a resin flow path communicating the cavity with the cavity, wherein the resin flow path is provided and fitted into the resin sealing mold. And the resin flow path member is replaceable, and the specifications of the resin flow path are determined according to the substrate and the electronic component.
[0008]
According to this, since the specification of the resin flow path is determined according to the substrate and the electronic component, it is possible to fit the resin flow path member having the resin flow path of the optimum specification to the resin sealing mold. it can. Therefore, by exchanging the resin flow path member according to the substrate and the electronic component, it becomes possible to use a resin sealing mold having optimal specifications.
[0009]
In addition, in order to solve the above-mentioned technical problem, the resin sealing mold according to the present invention is used when collectively resin-sealing the electronic components mounted on the respective regions of the substrate. A resin sealing mold having a stored cull, a cavity into which a molten resin is injected, and a resin flow path communicating the cull and the cavity, wherein the resin sealing mold is closed in a state where the resin sealing mold is clamped. It has an air vent provided so as to communicate the outside of the stop mold with the cavity, and has an air vent member fitted in the resin sealing mold, and the air vent member is replaceable, and The specification is characterized in that it is determined according to the substrate and the electronic component.
[0010]
According to this, since the specifications of the air vent are determined according to the substrate and the electronic component, it is possible to fit the air vent member having the air vent of the optimum specification into the resin sealing mold. Therefore, by exchanging the air vent member according to the substrate and the electronic component, it becomes possible to use a resin sealing mold having optimal specifications.
[0011]
The resin sealing mold according to the present invention is characterized in that, in the above-described resin sealing mold, a plurality of cavities are provided, and a resin flow path or an air vent has a plurality of different specifications. .
[0012]
According to this, resin sealing is performed using a resin sealing mold having a plurality of resin flow paths or air vents having different specifications. Then, by examining the obtained molded product, it becomes possible to select a resin flow path or an air vent having an optimal specification.
[0013]
In addition, in order to solve the above-mentioned technical problem, the method for determining the specification of a resin-sealing mold according to the present invention is used for collectively resin-sealing electronic components mounted on respective regions of a substrate. For a resin sealing mold having a cull in which the molten resin is stored, a cavity into which the molten resin is injected, and a resin flow path communicating the cull and the cavity, the specifications of the resin sealing mold are determined. A method for determining the specifications of a resin sealing mold, wherein a step of preparing a replaceable resin flow path member provided with a resin flow path having a plurality of different specifications, and fitting the resin flow path member to the resin sealing mold Mounting, forming a molded product by resin-sealing the electronic components collectively using a resin-sealing mold, investigating the occurrence of defects in the molded product, and the results of the investigation Depending on the resin flow path with different specifications. Characterized by comprising the step of determining the specifications.
[0014]
According to this, resin sealing is performed using a resin sealing mold having a plurality of resin flow paths having different specifications, and a resin flow path having an optimal specification is determined by investigating the obtained molded product. can do. Therefore, it becomes possible to complete a resin sealing mold having a resin flow path with optimal specifications.
[0015]
In addition, in order to solve the above-mentioned technical problem, the method for determining the specification of a resin-sealing mold according to the present invention is used for collectively resin-sealing electronic components mounted on respective regions of a substrate. A cavity in which the molten resin is stored, a cavity into which the molten resin is injected, a resin flow path communicating the cavity with the cavity, and an air vent communicating the outside of the resin sealing mold with the cavity when the mold is clamped. A method for determining the specifications of the resin sealing mold, wherein the air vent having a plurality of different specifications is provided and a replaceable air vent member is provided. A step of preparing, a step of fitting an air vent member to the resin sealing mold, a step of forming a molded product by collectively resin sealing the electronic components using the resin sealing mold, Defective product A step of investigating the situation, according to the result of the investigation, characterized by comprising the step of determining the optimum design for the air vent having a plurality of different specifications.
[0016]
According to this, it is possible to determine an air vent having an optimal specification by performing resin sealing using a resin sealing mold having air vents having a plurality of different specifications and examining the obtained molded product. . Therefore, it is possible to complete a resin sealing mold having an air vent with optimal specifications.
[0017]
BEST MODE FOR CARRYING OUT THE INVENTION
(1st Embodiment)
Hereinafter, a first embodiment of a resin sealing mold according to the present invention will be described with reference to FIGS. FIG. 1 is a cross-sectional view showing a state in which resin sealing has been completed, together with a molded product, of a resin sealing mold according to the present invention. FIG. 2A is a partial plan view showing a main part of the resin sealing mold according to the present embodiment, and FIG. 2B is a diagram showing the molded resin and the resin sealing mold of FIG. It is sectional drawing which shows the completed state along the AA line. FIG. 3 is a partial plan view showing a modified example of the resin sealing mold according to the present embodiment.
[0018]
In FIG. 1, the upper mold 1 and the lower mold 2 are combined with a mold matching surface P. A resin sealing mold to be clamped by L is formed. Here, the upper mold 1 and the lower mold 2 are resin molds made of a metal material represented by tool steel. The lower die 2 is provided with a concave portion 4 on which the multi-piece substrate 3 is placed. A block member 5 is fitted to the upper mold 1, and on the mold surface side of the upper mold 1, a cull 6 in which a molten resin (not shown) is stored, and a resin in which the molten resin flows through the cull 6 A channel 7 and a cavity 8 formed of a space into which the molten resin is injected are provided, respectively. The resin flow path 7 includes a runner portion communicating with the cull 6 and a gate portion which is a portion near the cavity 8. An air vent 9 is provided in the cavity 8 so that the cavity 8 communicates with the outside of the resin sealing mold in a state where the mold is clamped. In the block member 5, the resin flow path 7 and the air vent 9 are fitted with a resin flow path member 10 and an air vent member 11 which are separate members and which can be replaced. That is, the resin flow path 7 is formed in the resin flow path member 10, and the air vent 9 is formed in the air vent member 11. Further, the air vent 9 is formed so as to communicate from the air vent member 11 to the block member 5, extends toward the front side or the back side in the drawing, and communicates with the outside of the resin sealing mold.
[0019]
The lower mold 2 is provided with a pot 12 having a cylindrical space, and a plunger 13 is fitted in the pot 12 so as to be able to move up and down. Further, both the upper mold 1 and the lower mold 2 are provided with a heater 14 for heating and melting the resin tablet and for preheating the substrate 3, and an eject pin 15 for projecting a molded product (described later), respectively. I have.
[0020]
A chip 16 such as a semiconductor chip is mounted on the substrate 3, and electrodes (not shown) of the chip 16 and the substrate 3 are connected by wires 17 such as gold wires. A predetermined area on the substrate 3, the chip 16, and the wire 17 are resin-sealed with a cured resin 18. The cured resin 18 is formed by curing the molten resin in the cull 6, the resin flow path 7, and the cavity 8. The substrate 3, the chip 16, the wires 17, and the cured resin 18 together form a molded product 19.
[0021]
A specific example of the resin sealing mold according to the present invention will be described with reference to FIG. In FIG. 2, a quadrangular portion surrounded by a two-dot chain line in the so-called four-piece substrate 3 is a region corresponding to an individual package, and a chip 16 is mounted in each region. Two resin flow paths 7 and two air vents 9 are provided for one cavity 8 for resin-sealing the four chips 16 mounted on the substrate 3. Each of the resin flow paths 7 is provided so as to take the shortest path from the cull 6 and expand from the middle in each area on one side of the substrate 3.
[0022]
Further, a modified example of the resin sealing mold according to the present invention will be described with reference to FIG. In FIG. 3, a quadrangular portion surrounded by a two-dot chain line is a region corresponding to an individual package in a so-called nine-unit substrate 3, and a chip 16 is mounted in each region. One resin flow path 7 and one air vent 9 are provided for one cavity 8 for resin sealing nine chips 16 mounted on the substrate 3. The resin flow path 7 extends from the cull 6 perpendicularly to one side of the substrate 3 and then obliquely moves so as to be perpendicular to one side of the substrate 3 near a corner of the substrate 3. , And the cavity 8. Further, the air vent 9 is provided at a position substantially opposite to the position where the resin flow path 7 is provided in the cavity 8 with a diagonal line therebetween.
[0023]
Here, the resin flow path member 10 and the air vent member 11 shown in FIGS. 2 and 3 are prepared in advance as follows. First, in accordance with the configurations of the substrate 3 and the chip 16, the dimensions and shapes of the resin flow path 7 and the air vent 9, that is, specifications, are determined in advance so as to be optimal. More specifically, for example, the resin flow path 7 and the air vent 9 are formed by experiments, simulations, and the like with respect to the number of chips and the size of each region on the substrate 3, the size of the chip 16, the number, length, and layout of the wires. Is determined in advance so that the specifications of the above are optimal. Next, the resin flow path member 10 and the air vent member 11 having such optimum specifications are manufactured, and prepared according to the substrate 3 and the chip 16 respectively. Thereby, the resin flow path 7 and the air vent 9 having the optimum specifications are selected according to the substrate 3 and the chip 16, and the resin flow path member 10 and the air vent member 11 having them are fitted to the block member 5. be able to.
[0024]
The operation of the resin sealing mold according to the present invention will be described with reference to FIG. First, a resin tablet (not shown), which is a material of molten resin, is supplied onto the plunger 13 in the pot 12. Then, the substrate 3 on which the chip 16 is mounted and wiring by the wires 17 is completed is placed in the concave portion 4 of the lower die 2 and the upper die 1 and the lower die 2 are clamped.
[0025]
Next, a molten resin (not shown) formed by heating and melting the resin tablet by the heater 14 is pressed by the plunger 13. Thus, the molten resin is injected into the cavity 8 via the cull 6 and the resin flow path 7 in order. Here, the air in the cavity 8 is discharged out of the resin sealing mold via the air vent 9 as the molten resin is injected into the cavity 8. Here, the inside of the cavity 8 may be sucked from the outside of the resin sealing mold via the air vent 9.
[0026]
Next, the molten resin is further heated and cured to form a cured resin 18. Thereafter, the upper mold 1 and the lower mold 2 are opened, and the eject pin 15 is protruded to take out the molded product 19 from the resin sealing mold. Then, the molded article 19 is unloaded by using an appropriate unloading means (not shown).
[0027]
As described above, according to the present embodiment, the resin flow path member 10 in which the resin flow path 7 is formed and the air vent member 11 in which the air vent 9 is formed are fitted into the block member 5, respectively. The specifications of the resin flow path 7 and the air vent 9 are both determined according to the substrate 3 and the chip 16, and the resin flow path member 10 and the air vent member 11 are replaceable. Thereby, it is possible to select a resin flow path 7 and an air vent 9 having the optimum specifications from the resin flow path 7 and the air vent 9 prepared in advance according to the substrate 3 and the chip 16. Then, the resin flow path member 10 and the air vent member 11 having the optimum specifications can be selected and fitted to the block member 5. Therefore, it is possible to use a resin sealing mold having optimal specifications according to the substrate 3 and the chip 16.
[0028]
(Second embodiment)
Hereinafter, a second embodiment of the present invention will be described with reference to FIG. FIG. 4 is a partial plan view showing a main part of the resin sealing mold according to the present embodiment. This embodiment is particularly effective when the substrate and the chip have no experience of resin sealing, or when the substrate and the chip use a molten resin having the same but different characteristics as in the related art.
[0029]
This embodiment is characterized in that a plurality of resin flow paths having different sizes and shapes are formed in one resin flow path member 10 for the same substrate 3 and chip 16 or the same configuration of the substrate 3 and chip 16. 7 is provided. Further, in one air vent member 11 for the same substrate 3 and chip 16 or the same substrate 3 and chip 16 having the same configuration, a plurality of air vents 9 having different sizes and shapes are provided. .
[0030]
A method for determining the specifications of the resin sealing mold according to the present embodiment will be described with reference to FIG. First, resin sealing is experimentally performed using the resin sealing mold shown in FIG. Next, the state of occurrence of defects in the obtained molded product is investigated. Next, an optimum size and shape, that is, specifications are determined from the plurality of types of the resin flow path 7 and the air vent 9 in accordance with the result of the investigation. Next, the resin flow path 7 and the air vent 9 having the optimum specifications are selected, and the resin flow path member 10 and the air vent member 11 having only these are fitted to the block member 5. Through the above steps, it is possible to determine the optimal specifications for the resin sealing mold and complete the resin sealing mold for mass production.
[0031]
If the resin flow path member 10 and the air vent member 11 prepared in advance do not have the resin flow path 7 and the air vent 9 having the optimum specifications, the resin flow path member 10 and the air vent member 11 are newly manufactured. I do. In this case, the resin flow path member 10 and the air vent member 11 may be manufactured such that the selected resin flow path 7 and the air vent 9 are provided over the whole of each.
[0032]
Thus, after conducting an experiment using the resin sealing mold of FIG. 4, the optimal resin flow path member 10 and the air vent member 11 can be prepared and replaced with the optimal members. Therefore, according to the prior art, compared to the need to prepare a plurality of types of the entire block member 5 in FIG. 1 or to remanufacture and replace the entire block member 5, According to this, it is greatly advantageous in terms of cost and lead time.
[0033]
Meanwhile, in FIG. 4, two cavities 8 and two different kinds of resin flow paths 7 having two different sizes and shapes communicating with the two cavities 8 are arranged on one side of the two rows of cavities 8 sandwiching the pot 6. An air vent 9 is shown. Actually, the resin flow path 7 and the air vent 9 communicating with all the cavities 8 of one row may have different sizes and shapes. Further, the resin flow path 7 and the air vent 9 communicating with all the cavities 8 of both rows may have different sizes and shapes. Further, the plurality of cavities 8 may be grouped, and the resin flow path 7 and the air vent 9 may have different sizes and shapes between the groups.
[0034]
In each of the above-described embodiments, the cull 6 is provided in common with the block member 5, and the resin flow path 7 is formed in the resin flow path member 10, which is another member, so that the resin flow path member 10 is 5 was fitted. However, the invention is not limited thereto, and the cull 6 and the resin flow path 7 can be formed in the same member as necessary, and the member can be fitted to the block member 5. According to this, the optimum size and shape of the cull 6 and the resin flow path 7 can be selected according to the specifications of the substrate 3 and the chip 16.
[0035]
Further, the configuration in which the electrodes of the substrate 3 and the chip 16 are wired using the wires 17 has been described. The present invention is not limited to this, and the present invention can be applied to a substrate adopting a so-called flip chip bonding configuration in which electrodes of the substrate 3 and the chip 16 are connected to face each other.
[0036]
In addition, the resin sealing mold made of a metal material represented by tool steel has been described. However, the present invention is not limited to this, and a non-metallic material such as ceramic can be used as a material forming the mold. Further, the block member 5, the resin flow path member 10 and the air vent member 11 may be made of different materials.
[0037]
Further, the resin flow path member 10 and the air vent member 11 were fitted to the block member 5 fitted to the resin sealing mold. However, the present invention is not limited thereto, and the resin flow path member 10 and the air vent member 11 may be directly fitted to the resin sealing mold. In any case, either one of the resin flow path member 10 and the air vent member 11 can be fitted.
[0038]
In addition to the dimensions and shape of the specifications of the resin flow path 7 and the air vent 9, for example, surface treatment such as plating of each member, material, and the like can be subjected to experiments, investigations, and determinations. In this case, the size and shape of the resin flow path 7 and the air vent 9 are made the same, and the surface treatment and the material of the resin flow path member 10 or the air vent member 11 are made different, so that the optimum surface treatment and The specifications such as the material can be determined.
[0039]
In addition, the resin flow path member 10 and the air vent member 11 have been described as integral members. However, the present invention is not limited thereto, and the resin flow path member 10 or the air vent member 11 may be configured by combining members corresponding to one or a plurality of cavity units.
[0040]
In addition, the present invention is not limited to the above-described embodiments, and may be arbitrarily and appropriately combined, changed, or selected as needed without departing from the spirit of the present invention. You can do it.
[0041]
【The invention's effect】
According to the present invention, the specifications of the resin flow path and the air vent are determined according to the substrate and the electronic component, and the resin flow path member in which the resin flow path is formed and the air vent member in which the air vent is formed are each a block member. It is fitted so as to be exchangeable. As a result, the resin flow path member and the air vent member determined according to the substrate and the electronic component are fitted to the resin sealing mold, so that a resin sealing mold having optimal specifications can be used. become. Also, for the same substrate and electronic component, a resin sealing mold in which one resin flow path member has resin flow paths having different specifications, or a plurality of different air vent members have different air flow path members. A resin sealing mold provided with an air vent having the following specifications is used. Thereby, the optimal specification of the resin sealing mold for the substrate and the electronic component is determined, and a resin flow path member or an air vent member having a resin flow path or an air vent of those specifications is fitted to the block member, A resin sealing mold can be completed. Therefore, the present invention provides an excellent resin sealing mold having a specification in which a defect is unlikely to occur, and a method for determining the specification of the resin sealing mold capable of easily determining such a specification. It has a practical effect.
[Brief description of the drawings]
FIG. 1 is a cross-sectional view showing a state in which resin sealing has been completed, together with a molded product, of a resin sealing mold according to the present invention.
FIG. 2 (1) is a partial plan view showing a main part of a resin sealing mold according to a second embodiment of the present invention, and FIG. 2 (2) is a resin molding of FIG. 2 (1) together with a molded product. It is sectional drawing which shows the state which completed resin sealing about the sealing mold along the AA line.
FIG. 3 is a partial plan view showing a modified example of the resin sealing mold according to the first embodiment of the present invention.
FIG. 4 is a partial plan view showing a main part of a resin sealing mold according to a second embodiment of the present invention.
[Explanation of symbols]
1 Upper mold (resin sealing mold)
2 Lower mold (resin sealing mold)
3 Substrate 4 Recess 5 Block member 6 Cal 7 Resin flow path 8 Cavity 9 Air vent 10 Resin flow path member 11 Air vent member 12 Pot 13 Plunger 14 Heater 15 Eject pin 16 Chip (electronic component)
17 Wire 18 Cured resin 19 Molded product

Claims (5)

Used when collectively sealing the electronic components mounted on the respective regions of the substrate with a resin, a cull in which the molten resin is stored, a cavity in which the molten resin is injected, and the cull and the cavity. A resin sealing mold having a communicating resin flow path,
The resin flow path is provided and includes a resin flow path member fitted in the resin sealing mold,
The resin sealing member is exchangeable, and a specification of the resin channel is determined according to the substrate and the electronic component. Used when collectively sealing the electronic components mounted on the respective regions of the substrate with a resin, a cull in which the molten resin is stored, a cavity in which the molten resin is injected, and the cull and the cavity. A resin sealing mold having a communicating resin flow path,
An air vent provided to communicate the outside of the resin sealing mold and the cavity in a state where the resin sealing mold is clamped, and an air vent fitted to the resin sealing mold; With the members,
The air sealing member is replaceable, and a specification of the air vent is determined according to the substrate and the electronic component. The mold for resin sealing according to claim 1 or 2,
The plurality of cavities are provided,
A resin sealing mold, wherein the resin flow path or the air vent has a plurality of different specifications. Used when collectively sealing the electronic components mounted on the respective regions of the substrate with a resin, a cull in which the molten resin is stored, a cavity in which the molten resin is injected, and the cull and the cavity. A resin sealing mold having a resin flow path communicating with the resin sealing mold, a method for determining the specification of the resin sealing mold for determining the specification of the resin sealing mold,
A step of preparing a replaceable resin flow path member provided with the resin flow path having a plurality of different specifications,
A step of fitting the resin flow path member in the resin sealing mold,
A step of forming a molded product by collectively sealing the electronic component with the resin using the resin sealing mold;
Investigating the occurrence of defects for the molded article,
Deciding an optimum specification for the resin flow path having a plurality of different specifications in accordance with the result of the investigation. Used when collectively sealing the electronic components mounted on the respective regions of the substrate with a resin, a cull in which the molten resin is stored, a cavity in which the molten resin is injected, and the cull and the cavity. A resin that determines the specifications of the resin sealing mold for the resin sealing mold having the resin flow path communicating therewith and an air vent communicating the outside of the resin sealing mold and the cavity in a clamped state. A method for determining specifications of a sealing mold,
Preparing a replaceable air vent member provided with the air vent having a plurality of different specifications,
A step of fitting the air vent member in the resin sealing mold,
A step of forming a molded product by collectively sealing the electronic component with the resin using the resin sealing mold;
Investigating the occurrence of defects for the molded article,
Determining an optimum specification for the air vent having a plurality of different specifications in accordance with the result of the investigation.

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