JP2015136872A - Resin spacer, insert molding product and production method thereof - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an insert molding method in which an insert component is held by plural support pins, and molten resin is flown into a mold cavity using an injection molder, and then the molten resin is cooled and solidified for integrating it with the insert component, capable of acquiring an insert molding product having no opening generated by the support pins.SOLUTION: A resin spacer of the invention is a resin spacer for holding the insert component during insert molding, and comprises: a body part; and a rib part which is a thin part disposed over whole circumference of the body part. The rib part is formed of resin whose kind is same to that of molding resin or resin having compatibility to molding resin used for insert molding, and at least part of the rib is integrated with the molding resin by melting an outermost circumference.

Description

  The present invention relates to a method for forming an insert part in which the insert part is installed in a mold and integrally molded in a form covered with a resin member.

  Various methods have been proposed as conventional insert molding methods. For example, an insert part is held in a mold using a plurality of support pins, and after a predetermined time has elapsed, the support pins are gradually retracted, and a molten resin is filled and fused in the space formed between the insert molding member and the support pins. Then, there is a method of manufacturing an insert injection molded product by covering the entire periphery of the insert molded member with resin (for example, see Patent Document 1 or 2).

  As another method, a fixing member for fixing the insert part in the cavity is manufactured by resin molding, the fixing member is arranged in the cavity together with the insert part, and the insert part is positioned. Thereafter, a method is known in which molten resin is filled into a cavity and molded (for example, see Patent Document 3). If this method is used, since the fixing member is integrated with the insert part without using a support pin as shown in Patent Document 1 or 2, an insert injection molded product without an opening generated when the support pin is pulled out. Can be obtained.

  Certainly, if a fixing member is used, it is possible to obtain an insert molded product that does not have pin marks or openings in appearance, but even if the fixing member is made of the same material as the molding resin used for insert molding Usually, the molding resin and the fixing member are separate members, and since the surface does not rise to a temperature at which the surface of the fixing member can be completely melted, the interface is not completely fused. For this reason, unevenness is formed on the surface of the fixing member, and processing such as mechanically improving adhesion is performed, but the interface is not completely fused, so that airtightness and watertightness can be maintained. Absent.

  When the insert part is made of metal, corrosion due to corrosive gas or moisture may occur depending on the use environment. Although an adhesive can be applied to the fixing member to ensure hermeticity such as airtightness and watertightness, the adhesive application process increases in the manufacturing process, resulting in an increase in manufacturing cost.

  As another method, there is a technique in which a ring-shaped rib is installed on the outer peripheral portion of a resin-made insert part itself, and the rib is melted and sealed during insert molding (see, for example, Patent Document 4).

JP 2006-142729 A JP 2010-234641 A JP 2004-174839 A Japanese Patent Laid-Open No. 2005-28828

  However, in the technique disclosed in the above-mentioned prior art document 1 or 2, the resin around the support pin is usually completely used to retract the support pin and fill the gap into the gap during filling with molten resin in insert molding. It cannot be solidified. In particular, the resin needs to be sufficiently melted around the support pins in contact with the insert parts. However, if the support pin is retracted while the resin is melted, the positioning of the insert part is likely to be unstable. If the support pins can be retracted in small numbers in order according to the solidification state of the resin among multiple support pins, positioning to a certain extent is possible. It is difficult to position.

  Further, in the technique disclosed in the above-mentioned prior art document 3, if a fixing member is used, it is possible to obtain an insert molded product having no pin marks or openings in appearance, but the fixing member is used for insert molding. Even if it is made of the same material as the molding resin to be used, the molding resin and the fixing member are usually separate members, and the surface of the fixing member does not rise to a temperature at which it can be completely melted. Does not fuse completely. For this reason, unevenness is formed on the surface of the fixing member, and processing such as mechanically improving adhesion is performed, but the interface is not completely fused, so that airtightness and watertightness can be maintained. Absent.

  When the insert part is made of metal, corrosion due to corrosive gas or moisture may occur depending on the use environment. Although an adhesive can be applied to the fixing member to ensure hermeticity such as airtightness and watertightness, the adhesive application process increases in the manufacturing process, resulting in an increase in manufacturing cost.

  Moreover, in the technique disclosed in the above-mentioned prior art document 4, as a condition for installing the rib, the insert part is limited to the resin molded product and is also restricted by the shape of the insert part. Only applies to

  The present invention has been made in order to solve the above-described problems, and ensures the sealing property such as airtightness and watertightness, and the shape of the resin spacer that can hold the insert part, and the resin spacer The present invention provides a method for forming an insert part using the above.

  The resin spacer according to the present invention is a resin spacer that holds an insert part during insert molding, and includes a main body part and a rib part that is a thin part provided around the main body part. The part is made of a resin that is the same type or compatible with the molding resin used for insert molding, and is molded integrally with the molding resin so that at least a part thereof melts the outermost periphery.

  According to the present invention, the resin spacer and the insert component molding method using the resin spacer can be used to reliably position the insert component with an easy method and have excellent sealing properties such as airtightness and watertightness. An insert molded product can be obtained.

It is a perspective view of the resin spacer which concerns on Embodiment 1 of this invention. It is sectional drawing which showed the state which hold | maintained the insert component which concerns on Embodiment 1 of this invention in the cavity of a metal mold | die. It is sectional drawing of the insert molded product which concerns on Embodiment 1 of this invention. It is a perspective view of the resin spacer which concerns on Embodiment 1 of this invention. It is sectional drawing of the resin spacer which concerns on Embodiment 1 of this invention. It is a perspective view of the resin spacer which concerns on Embodiment 1 of this invention. It is a perspective view of the insert component which concerns on Embodiment 1 of this invention. It is a perspective view of the insert molded product which concerns on Embodiment 1 of this invention. It is a perspective view of the resin spacer which concerns on Embodiment 2 of this invention. It is sectional drawing which showed the state which hold | maintained the insert component which concerns on Embodiment 2 of this invention in the cavity of a metal mold | die. It is a perspective view of the insert molded product which concerns on Embodiment 2 of this invention. It is a perspective view of the resin spacer which concerns on Embodiment 3 of this invention. It is a perspective view of the resin spacer which concerns on Embodiment 3 of this invention. It is a perspective view of the resin spacer which concerns on Embodiment 3 of this invention.

Embodiment 1 FIG.
Next, embodiments of the present invention will be described with reference to the drawings. In the following description of the drawings, the same or similar parts are denoted by the same or similar reference numerals. However, it should be noted that the drawings are schematic and ratios of dimensions and the like are different from actual ones. Therefore, specific dimensions and the like should be determined in consideration of the following description. Moreover, it is a matter of course that portions having different dimensional relationships and ratios are included between the drawings.

  First, a resin spacer according to Embodiment 1 of the present invention will be described. FIG. 1 is a perspective view showing a resin spacer according to Embodiment 1 of the present invention. FIG. 2 is a cross-sectional view showing a state in which the insert part is held in the cavity of the mold. In the figure, the resin spacer 1 is manufactured by using, for example, an injection molding method, and a part of the side surface portion 3 is shared along with the cylindrical main body portion 2 and the side surface portion 3 of the main body portion 2. A rib portion 4 having a disk-like thin wall portion provided around the body portion 2 so as to surround the body portion 2 (hereinafter sometimes referred to as “rib” only), and an upper surface of the body portion 2. The first main surface 5 on the side in contact with the support pin 17 and the second main surface 6 on the lower surface of the main body 2 and in contact with the insert component 16, A recess 7 is provided for holding the support pin 17 and positioning the resin spacer 1 so as not to shift during resin filling.

  In addition, although the case where the main-body part 2 was cylindrical shape was shown here, it is not necessary to limit to a cylindrical shape in particular, and if it is a shape which can hold | maintain the insert component 16 via the support pin 17, it will be a square pillar shape. However, other prismatic shapes may be used, and the vertical cross section may not necessarily be a columnar shape but may be a trapezoidal shape. Also, strict accuracy is not necessary for the shape. In extreme cases, the shape is not particularly limited as long as the above functions can be ensured even when the shape is spherical or elliptical.

  In addition, the rib portion 4 has a disc shape here, but it does not have to have a disc shape as long as it is provided so as to go around the main body portion 2. For example, it may be an ellipse, a square flat plate, or a wavy shape instead of a flat plate. In addition, although the main-body part is made into the cylinder here, when it has the below-mentioned collar part etc. which the main-body part surrounds the circumference | surroundings, the main-body part and rib which have a collar part even if it does not touch the cylindrical part of a main-body part directly So that the rib part is at least part of the main body and the boundary between the molten resin and the resin spacer connected from the boundary between the insert part and the resin spacer is not directly connected to the outside of the insert molded product. As long as the rib portion is provided so as to go around the main body portion, it is obvious that a sealed space can be formed and the effects of the present invention can be achieved. Further, the rib height 8 and the rib thickness 9 of the rib portion 4 will be described later. However, the rib height 8 and the rib thickness 9 are particularly defined as long as the above functions can be ensured depending on the design conditions. It is not a thing.

  Next, a method for holding the insert part 16 in the mold will be described. The insert component 16 is held by a support pin 17 in the form of a resin spacer 1 up and down in a cavity 15 that is a space formed between a fixed mold 11 and a movable mold 12 of the mold. The stationary mold 11 is provided with a support pin 17 as well as a resin inlet 14 for pouring molten resin. Further, the movable side mold 12 is provided with a support pin 17, as well as with an ejection pin 13 for removing the insert molded product solidified after resin molding from the movable side mold 12. Here, the upper mold of the mold is the fixed side mold and the lower mold is the movable side mold. However, which side is fixed and which side is movable is a design matter and is particularly limited. It is not a thing.

  Next, the insert part molding method (injection molding method) according to Embodiment 1 of the present invention will be described with reference to FIG. First, the resin spacer 1 is installed on the support pin 17 provided on the movable mold 12 with the first main surface 5 facing downward, and the insert component 16 is installed thereon. Resin spacers 1 are provided on the insert parts 16 at positions corresponding to the support pins 17 provided on the fixed mold 11, and the insert parts 16 are moved by moving the movable mold 12 upward. It is installed in the cavity 15 while being held by the support pins 17.

  Next, a resin melted by a resin melting device (not shown here because it is not directly related to the invention) provided from a resin inlet 14 provided in the stationary mold 11 (hereinafter referred to as a molten resin, Or, since it is used for insert molding, it may be described as molding resin). The molten resin is gradually cooled and solidified by coming into contact with a mold having a high thermal resistance but a high temperature. After the resin is completely solidified, the movable side mold 12 is moved downward to widen the space between the fixed side mold 11 and the insert part 16 is pushed upward by the protruding pin 13 so that the insert part 16 is moved to the movable side. Remove from mold 12.

  FIG. 3 is a cross-sectional view showing an insert molded product manufactured by the above method. In the figure, the insert molded product 20 has a structure that is solidified with a solidified resin 21 with the resin spacers 1 disposed above and below the insert part 16. In the solidified resin 21, a pin hole 22 exists in a portion held by the support pin 17. In this figure, the rib portion 4 is shown around the resin spacer 1 for easy understanding. However, since the rib portion 4 is thin and has a small heat capacity, when the molten resin is poured, All are melted, and at least at the tip of the rib, the entire circumference is melted by the molding resin and solidifies in a state of being integrated with the molten resin. Therefore, a gap between the molten resin poured into the resin and the resin spacer 1 is completely sealed at least at the rib portion 4, and an insert-molded article having excellent sealing properties such as airtightness and watertightness can be obtained. As a result, the insert-molded insert part is less likely to be corroded by atmospheric gas or moisture, and the reliability of the insert-molded product is improved.

  Next, the insert part molding method (injection molding method) described above will be described using a specific example. First, a thermoplastic resin made of the same material as the resin spacer 1 is used as the molten resin used for injection molding. The melt temperature of the molten resin was set to 320 ° C., the mold temperature was set to 130 ° C., and the process was performed under normal injection molding conditions. After the thermoplastic resin was cooled to the mold temperature in the mold, the insert molded product shown in FIG. 3 was taken out. At this time, it is desirable to use a thermoplastic resin made of the same material as the resin spacer 1 as the molten resin used for the injection molding. However, a resin made of the same material as long as it is the same kind of resin or a resin compatible with each other. It doesn't have to be.

  As the thermoplastic resin, the following resins that can be injection-molded can be used. For example, polypropylene resin, polyethylene resin, polystyrene resin, acrylonitrile / butadiene / styrene copolymer resin, acrylonitrile / styrene copolymer resin, polymethyl methacrylate resin, polybutylene terephthalate resin, polyethylene terephthalate resin, polycarbonate resin, polyacetal resin, poly Methyl pentene resin, modified polyphenylene ether resin, polyphenylene sulfide resin, liquid crystal polymer, polyamide resin, polyamide imide resin, polyether ether ketone resin, polyether imide resin, polyether sulfone resin, tetrafluoroethylene perfluoroalkyl vinyl ether copolymer resin , Polyvinylidene fluoride resin, polyimide resin, polysulfone resin, syndiotactic Polystyrene resin, or poly ether sulfone resin, and the like. Glass fiber, carbon fiber, whisker, inorganic filler or the like may be blended therein.

  Moreover, there exists a more preferable range in the thickness of a rib part, and the height of a rib part. If the thickness of the rib portion is too thin, the resin is difficult to flow into the portion where the rib portion is formed during molding of the resin spacer, and there is a possibility that molding cannot be performed well. Further, if the rib portion is too thick, it takes time for heat transfer from the molten resin, so that the rib portion is difficult to melt and cannot be completely integrated with the molten resin. Furthermore, if the rib part is too narrow, it is difficult to melt by cooling from the main body part of the resin spacer, and if the rib part is too wide, the flow length of the resin in the part that forms the rib part during molding of the resin spacer becomes long. There is a possibility that the resin is difficult to flow into the portion where the rib portion is formed and cannot be molded well.

  In the above description, the resin spacer has been described with one rib portion, that is, a single rib portion. However, for example, as shown in FIGS. 4 and 6, two rib portions are formed, that is, double. It is desirable to form. This is because, by forming a plurality of rib portions, seal portions that are completely separated from the outside by the rib portions are formed in multiple layers, and the sealing performance such as airtightness and watertightness is further improved. In addition, since the direction which changed rib height, rib thickness, or rib height and rib thickness can respond to a shaping | molding dispersion | variation flexibly, it can seal more reliably. In addition, although two (double) cases have been described here, other multiple structures such as triple, quadruple, etc. may be used.

  Hereinafter, the more preferable range about the thickness of a rib part and the height of a rib part is demonstrated. The range of the thickness t (unit m) of the rib portion is defined by the following formula 1.

ここで、ｔ_ｍｉｎ（単位ｍ）、ｔ_ｍａｘ（単位ｍ）は、下記数式２及び３でそれぞれ求められる。

Here, t _min (unit m) and t _max (unit m) are obtained by the following mathematical formulas 2 and 3, respectively.

  The range of the height L (unit m) of the rib portion is defined by the following mathematical formula 4.

Ｌｍｉｎ（単位ｍ）およびＬｍａｘ（単位ｍ）は、採用したｔの値を用いて、それぞれ下記数式５及び６で求められる。

Lmin (unit m) and Lmax (unit m) are obtained by the following formulas 5 and 6, respectively, using the adopted t value.

Here, η is the viscosity at the molding temperature of the resin used for the resin spacer, more preferably a value (unit Pa · s) near a shear rate of 100 (1 / s), and α is used for the resin spacer. thermal diffusion coefficient of the resin (unit m ^{2 /} s), Tm is the melting temperature of the resin used in the resin spacer (unit ° C.), Ts is the temperature (in ° C.) of the molten resin (molding resin), T ₀ is the resin spacer The initial temperature (unit: ° C). Further, the denominator m in Equation 6 is obtained by Equation 7 below.

ここで、λは、樹脂スペーサに用いられる樹脂の熱伝導率（単位Ｗ／ｍ・Ｋ）である。

Here, λ is the thermal conductivity (unit: W / m · K) of the resin used for the resin spacer.

Example 1.
Polybutylene terephthalate (PBT) resin is used for the resin spacer, and glass fiber reinforced PBT resin manufactured and sold by Mitsubishi Engineering Plastics. Similarly, by using 5010G30, the metal insert part 51 shown in FIG. 7 was injection-molded at a molding resin melting temperature of 260 ° C. Here, resin spacers 52 and 53 were previously attached to the metal insert part 51. In the drawing, the resin spacers 52 and 53 are shown with a single rib portion, but the outline of the shape of the metal insert part and the position of the resin spacer is shown. As shown below, a double rib portion was used.

  The resin spacer used at this time has a disk-shaped flange protruding from the vicinity of the second main surface along the side surface on the columnar shape, as shown in FIGS. A rib part extending vertically concentrically from the collar part of the hat-shaped main body part is provided. 4 is a perspective view of the resin spacer according to the first embodiment of the present invention, and FIG. 5 is a cross-sectional view of the resin spacer according to the first embodiment of the present invention.

  4 and 5, the resin spacer 31 is manufactured by using, for example, an injection molding method, and a disc-shaped flange protruding from the vicinity of the second main surface along the cylindrical side surface 33. 34, a main body portion 32 having a hat shape, a first rib portion 38 having a thin wall portion extending vertically on the outer concentric circle from the flange portion 34, and extending vertically on the inner concentric circle from the flange portion 34. The second rib portion 39 having a thin portion, the first main surface 35 on the upper surface of the main body portion 32 on the side where the support pin 17 contacts, and the lower surface of the main body portion 32 on the side in contact with the insert component 16. The first main surface 35 is provided with a recess 37 for holding the support pin 17 and positioning the resin spacer 31 so that the position of the resin spacer 31 does not shift during resin filling. ing.

  Here, the first rib portion 38 and the second rib portion 39 having thin wall portions extending vertically on the concentric circle from the flange portion 34 of the main body portion 32 are illustrated, but the rib portion exists particularly on the concentric circle. do not have to. As long as the side portion 33 is provided so as to surround the entire circumference, it may be oval or polygonal. Also, strict accuracy is not necessary for the shape. In an extreme case, the shape is not particularly limited as long as the above function can be ensured even if the shape is distorted.

  As for the resin spacer used this time, the rib height 91 of the first rib portion 38 arranged on the outside shown in the figure is 1.5 (mm), the rib thickness 92 is 0.3 (mm), and the resin spacer is arranged on the inside. The rib height 93 of the second rib portion 39 is 1 (mm), and the rib thickness 94 is 0.3 (mm).

The rib height and rib thickness were determined so as to satisfy the above formulas 1-7. The viscosity at 260 ° C. of 5010G30 is about 230 (Pa · s) at a shear rate of 100 (1 / s), the thermal diffusion coefficient is 1.76 × 10 ⁻⁷ (m ² / s), and the thermal conductivity is 0.00. 25 (W / m · K), the melting temperature is 224 (° C.), the temperature of the molding resin is 260 (° C.), and the initial temperature of the resin spacer is 25 (° C.), the rib thickness range is 0.06 to It was 0.90 (mm), and 0.3 (mm) included in this range was adopted. Furthermore, the rib height range at a rib thickness of 0.3 (mm) can be calculated as 0.36 to 5.11 (mm), and the double rib height is 1.5 (mm) included in this range. ) And 1 (mm).

  The appearance of the insert-molded product molded as described above is shown in FIG. At the same time, in order to confirm the cross-sectional shape in detail, another insert molded product using PBT resin of the same grade and using PBT resin having different colors (hereinafter sometimes referred to as “different color resin”) was also molded.

  It was confirmed that the insert molded product taken out from the mold could be molded without any problems by visual inspection. Therefore, the resin spacer portion of the insert molded product molded with a different color resin was cut out, and the cross section was cut and observed in detail with a microscope. It was confirmed that resins of different colors were mixed at the rib interface, and the ribs of the resin spacer were melted and fused with the molding resin.

  As described above, according to the present invention, when the molding resin fills the cavity and is integrated with the insert part, the resin spacer is also integrated, and at this time, the rib having a small heat capacity is melted by heating from the molding resin. Since it is fused with the molding resin, it is possible to obtain an insert molded product having excellent sealing properties such as airtightness and watertightness.

  In addition, since the insert part is supported by a resin spacer separately molded in the mold, there is no major restriction on the shape of the insert part, and a small surface in contact with the resin spacer only needs to be secured.

  In addition, when the molten rib is installed in the insert part itself, the insert part is limited to resin, but if the resin spacer of the present invention is used, the material of the insert part does not need to be particularly limited, and resin is of course. Also, metal or ceramic can be used.

Example 2
The resin spacer is a polyamide MXD6 (PA-MXD6) resin, which is a polyamide resin, and is a glass fiber reinforced PA-MXD6 resin manufactured and sold by Mitsubishi Engineering Plastics. In the same manner, 1002F was also used as the molding resin, and the same resin spacer as in Example 1 was used at a melting temperature of the molding resin of 280 ° C., and injection molding was performed in the same manner.

The rib height and rib thickness were determined so as to satisfy the above formulas 1-7. 1002F has a viscosity at 280 ° C. of about 490 (Pa · s) at a shear rate of 100 (1 / s), a thermal diffusion coefficient of 1.49 × 10 ⁻⁷ (m ² / s), and a thermal conductivity of 0.1. 21 (W / m · K), the melting temperature is 243 (° C.), calculated as the molding resin temperature 280 (° C.) and the resin spacer initial temperature 25 (° C.), the rib thickness range is 0.09 to It was 0.82 (mm), and 0.3 (mm) included in this range was adopted. Furthermore, the rib height range at a rib thickness of 0.3 (mm) can be calculated as 0.34 to 3.50 (mm), and the double rib height is 1.5 (mm) included in this range. ) And 1 (mm).

  As in Example 1, the insert molded product taken out from the mold was confirmed to have been formed without any problem by appearance inspection. Therefore, the resin spacer portion of the insert molded product molded with a different color resin was cut out, and the cross section was cut and observed in detail with a microscope. It was confirmed that resins of different colors were mixed at the rib interface, and the ribs of the resin spacer were melted and fused with the molding resin.

Example 3
The resin spacer is a polyphenylene sulfide (PPS) resin, a glass fiber reinforced PPS resin manufactured and sold by Polyplastics, and the product name is DURAFIDE 1140A6 (hereinafter sometimes referred to as 1140A6 only), and the molding resin is also used. Similarly, 1140A6 was used and injection molding was performed in the same manner using the same resin spacer as in Example 1 above at a molding resin melting temperature of 320 ° C.

The rib height and rib thickness were determined so as to satisfy the above formulas 1-7. The viscosity at 320 ° C. of 1140A6 is about 660 (Pa · s) at a shear rate of 100 (1 / s), the thermal diffusion coefficient is 1.88 × 10 ⁻⁷ (m ² / s), and the thermal conductivity is 0.1. 27 (W / m · K), the melting temperature is 285 (° C.), and when calculated as the molding resin temperature 320 (° C.) and the resin spacer initial temperature 25 (° C.), the rib thickness ranges from 0.10 to 0.10. It was 0.88 (mm), and 0.3 (mm) included in this range was adopted. Further, the rib height range at a rib thickness of 0.3 (mm) can be calculated as 0.35 to 2.01 (mm), and the double rib height is 1.5 (mm) included in this range. ) And 1 (mm).

  As in Example 1, the insert molded product taken out from the mold was confirmed to have been formed without any problem by appearance inspection. Therefore, the resin spacer portion of the insert molded product molded with a different color resin was cut out, and the cross section was cut and observed in detail with a microscope. It was confirmed that resins of different colors were mixed at the rib interface, and the ribs of the resin spacer were melted and fused with the molding resin.

  About the said Example, the insert molded article was manufactured by embodiment described above using the resin spacer shown in FIG. 1 shape | molded by changing the kind of resin, rib height, or rib thickness, respectively. A resin spacer portion of an insert-molded product molded with a different color resin was cut out, the cross section was cut and observed in detail with a microscope, and the fusing property at the rib interface was evaluated.

  The evaluation results are shown in Table 1 below. The boundary varies depending on the type of resin, but generally, as the rib thickness increases and the rib height decreases, the meltability of the rib interface decreases. The thinner the rib thickness, the better the fusing property. However, if the rib thickness is extremely thin, the resin fluidity at the time of molding is lowered and it becomes difficult to mold by injection molding. Although such an example is described as a comparative example, Comparative Examples 1 to 3 in which a part of the ribs are not melted or the molding of the ribs is difficult do not satisfy Expressions 1 to 7. In order to sufficiently melt the rib, it is desirable that the range of the rib height and the rib thickness satisfy the expressions 1 to 7.

Embodiment 2. FIG.
In the first embodiment described above, the method of forming the insert part using the support pin and holding the insert part via the resin spacer has been described. However, the support pin is used by giving the resin spacer the role of the support pin. It is also possible to mold the resin without using it. FIG. 9 is a perspective view of a resin spacer according to Embodiment 2 of the present invention. FIG. 10 is a sectional view showing a state in which the insert part according to the second embodiment of the present invention is held in the cavity of the mold. In the figure, the portions denoted by the numbers shown in the first embodiment are the same as the configurations described in the first embodiment, and thus the description thereof is omitted here.

  In the figure, the resin spacer 101 is provided with a convex portion 107 on the first main surface 5 for fitting with the concave portion 57 provided at a predetermined position facing the cavity 58 of the fixed side mold 55 and the movable side mold 56. The insert part 16 is held via a resin spacer 101 in a cavity 58 formed by a fixed side mold 55 and a movable side mold 56 that do not have a portion for accommodating the support pins 17. The resin spacer 101 is provided with a convex portion 107 for positioning the fixed side mold 55 or the movable side die 56 on the first main surface 5, and is fixed at a position facing the convex portion 107 for positioning. It engages with the recess 57 of the side mold 55 and the movable mold 56.

  In the same manner as in the first embodiment, the insert part was held using the PBT resin resin spacer shown in FIG. 9, and the PBT resin was insert molded as a molding resin. The resin spacer used here has a rib height of 1.5 mm and a wall thickness of 0.3 mm. FIG. 11 shows an insert-molded product molded in the embodiment of the present invention. In the figure, the resin spacer 101 of the insert-molded product 71 has a convex portion 107.

  As in Example 1, the insert molded product taken out from the mold was confirmed to have been formed without any problem by appearance inspection. Therefore, the resin spacer portion of the insert molded product molded with a different color resin was cut out, and the cross section was cut and observed in detail with a microscope. It was confirmed that resins of different colors were mixed at the rib interface, and the ribs of the resin spacer were melted and fused with the molding resin.

  As described above, according to the present embodiment, the injection molding in which the insert part is installed in the mold, and the molten resin is poured into the mold cavity by using an injection molding machine and solidified by cooling and integrated with the insert part. In the insert molding method using this method, there can be provided a method for obtaining an insert molded product having no opening caused by the support pin and having excellent hermeticity.

Embodiment 3 FIG.
In the second embodiment described above, the main body portion of the resin spacer has been described as having a cylindrical shape that does not have a complicated uneven shape. However, for example, the main body portion may have a shape having an undercut portion. . 12-14 shows an example of the resin spacer which has an undercut part in a main-body part. The undercut portion usually refers to a concave-convex shape that cannot be released as it is when the molded product is taken out from the mold. It shall refer to the formed uneven shape in general. The reason why the undercut portion is provided is that the molding resin flows into the concave portion formed in the undercut portion, thereby fitting with the convex portion and producing an effect that the resin spacer and the molding resin are more firmly bonded. In the figure, the portions denoted by the numbers shown in the above embodiment are the same as the configurations described in the above embodiment 1, and thus the description thereof is omitted here.

  In the present embodiment, an insert-molded product was molded using the resin spacer 76, the resin spacer 86, and the resin spacer 96 shown in FIGS. The undercut portions of the resin spacer 76, the resin spacer 86, and the resin spacer 96 are indicated by an undercut portion 77, an undercut portion 87, and an undercut portion 97, respectively. Further, the rib portion of the resin spacer 76 is indicated by a first rib portion 78 and a second rib portion 79, the rib portion of the resin spacer 86 is indicated by a rib portion 88, and the rib portion of the resin spacer 96. Is indicated by a rib portion 98. Here, the wall portion 89 of the resin spacer 86 seems to constitute a rib portion. However, since the rib portion is actually formed very thin, the entire surface does not melt in the process of pouring the molding resin. Such a wall cannot be a rib. However, whether it is a wall or a rib is a design matter related to how the height and thickness are to be determined, so it cannot be determined by the location provided or the appearance alone. The effect that it has is important.

  The insert molded product formed by using the resin spacer 76, the resin spacer 86, and the resin spacer 96 and taken out from the mold is filled with the molding resin in the undercut portion in the appearance inspection, and can be molded without any problem. confirmed. In the insert molded product molded using the resin spacer according to the present embodiment, the undercut portion is filled with molding resin, and the surface exposed area of the resin spacer is reduced. As a result of cutting out a test piece including the resin spacer portion and performing a bending test, the resin spacer 1 is 1.5 times the resin spacer 76, 1.6 times the resin spacer 86, and the resin spacer 96. It was confirmed that the strength was improved by about 1.9 times.

  As described above, according to the present embodiment, since the area of the interface between the resin spacer and the molding resin can be widened, not only the bending strength of the insert molded product can be increased, but also the resin spacer and the molding resin. It is possible to obtain an insert molded product that is difficult to separate.

DESCRIPTION OF SYMBOLS 1 Resin spacer, 2 Main-body part, 3 Side part, 4 Rib part, 5 1st main surface, 6 2nd main surface, 7 Recessed part, 8 Rib height, 9 Rib thickness,
DESCRIPTION OF SYMBOLS 11 Fixed side type | mold, 12 Movable side type | mold, 13 Extrusion pin, 14 Resin inflow port, 15 Cavity, 16 Insert component, 17 Support pin,
20 insert molded product, 21 resin, 22 pin hole,
31 resin spacer, 32 body portion, 33 side surface portion, 34 flange portion, 35 first main surface, 36 second main surface, 37 concave portion, 38 first rib, 39 second rib,
41 resin spacer, 42 body portion, 43 side surface portion, 45 first main surface, 46 second main surface, 47 recess, 48 first rib, 49 second rib,
51 metal insert parts, 52 resin spacers, 53 resin spacers,
55 Fixed side mold, 56 Movable side mold, 57 Recess, 58 Cavity 61 Insert molded product 71 Insert molded product 76 Resin spacer, 77 Undercut part, 78 First rib part, 79 Second rib part 86 Resin spacer, 87 Undercut portion, 88 rib portion, 89 wall portion 91 rib height of first rib portion, 92 rib thickness of first rib portion, 93 rib height of second rib portion, 94 of third rib portion Rib thickness,
96 resin spacer, 97 undercut part, 98 rib part,
101 Resin spacer, 107 Convex

Claims (9)

A resin spacer for holding an insert part during insert molding,
The main body,
A rib part that is a thin part provided around the body part;
The rib portion is made of a resin having the same type or compatibility with a molding resin used for insert molding, and is a resin spacer that is molded integrally with the molding resin so that at least a part thereof melts the outermost periphery.   The resin spacer according to claim 1, wherein the rib portion is provided at a plurality of locations.   3. The resin spacer according to claim 1, wherein a concave portion that engages with a support pin that supports the insert component is provided on a surface of the main body portion that is opposite to a surface that contacts the insert component. .   The convex part which fits with the metal mold | die which comprises the cavity which is the space into which the said molding resin is poured is provided in the surface opposite to the surface which contact | connects the said insert component of the said main-body part, The Claim 1 or Claim characterized by the above-mentioned. The resin spacer according to any one of 2 above. Insert parts,
A plurality of resin spacers fixed in contact with the surface of the insert component;
A molding resin provided to include at least a part of the insert part and at least a part of the resin spacer;
The resin spacer has a rib part that is a thin part provided around the circumference, and an insert that is molded integrally with the molding resin so that at least a part of the rib part melts the outermost periphery. Molding.   The insert molded product according to claim 5, wherein the rib portion is provided at a plurality of locations.   The insert molded product according to claim 5, wherein the rib portion is made of a resin having the same kind or compatibility with the molding resin. A method for producing an insert-molded product according to any one of claims 5 to 7,
The insert through a resin spacer between the mold and a cavity of a mold including a fixed mold having a fixed resin inlet and a movable mold in which an insert part is disposed and movable. Holding the parts;
Pouring molten resin from the resin inlet into the cavity;
Cooling and solidifying the molten resin;
And a step of taking out the insert-molded product from the mold after the molten resin is cooled and solidified.   The step of holding the insert component is a step of holding in the cavity of the mold via a support pin that supports the resin spacer and the insert component between the mold and the mold. Item 9. A method for producing an insert-molded article according to Item 8.

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