JP2001026035A - Method for insert molding and apparatus for insert holding - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a protective member which can prevent an insert resin from being deformed and broken when injection molding is performed regardless of resin strength and easily perform releasing of the insert resin after a molding resin is cooled. SOLUTION: A thin film coating layer 21 is formed in advance with a polytetrafluoroethylene containing a filler with a low frictional coefficient on the outer peripheral face of an insert material holding part 20a of a protective member 20A arranged on the inside of an insert material 30 and when insert molding is performed, an insert resin 30 is held from the inside through this coating layer 21.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an insert molding method having insert material protecting means for preventing deformation and breakage of an insert material in insert molding.

[0002]

2. Description of the Related Art Conventionally, with respect to a resin molded article of a cylindrical body, for example, a resin molded article attached to the tip of an antenna of a mobile phone, a molded resin is fixed to the outside of a previously molded insert material by insert molding. In this case, it is necessary to prevent the insert material from being damaged or deformed from the temperature and injection pressure of the molten resin when the molten resin of the thermosetting resin is injected into the molding die. A rod-shaped protection member is arranged inside the housing to hold the insert material.

FIG. 9 is a cross-sectional view showing a conventional insert molding method. In the drawing, reference numeral 1 denotes a molding die having a concave portion 1a having a circular or square cross-sectional shape.
It is divided into two by a mold opening surface 1d formed so as to cross substantially the center in the length direction. One split mold 1A is provided with a resin inflow passage 1c for press-fitting the molten resin during injection molding. This resin inflow channel 1c
Extends in the direction of the concave portion 1a from the opening provided in the end face of the split mold 1A, branches off at a right angle near the intermediate portion between the end face of the split mold 1A and the concave portion 1a, and has substantially the same length as the outer periphery of the concave portion 1a Is provided so that the concave portion 1a and the outside of the molding die 1 communicate with each other by being bent in the direction of the concave portion 1a. In the other split mold 1B, a hole 1b having a diameter smaller than that of the recess 1a is provided coaxially on an end face in the length direction of the recess 1a. Reference numeral 2 denotes a rod-shaped protection member as an insert material protection means disposed in the concave portion 1a of the mold 1,
An insert material holding portion 2a having one end formed to have a length in contact with the longitudinal end surface of the concave portion 1a and having a tapered surface having a predetermined gradient in the length direction, and a thick width of the insert material holding portion 2a. And a fixing portion 2b protruding so as to fit into a hole 1b provided in the split mold 1B. The fixing member 2b is fitted into the hole 1b of the protective member 2, and one end of the insert material holding portion 2a in the longitudinal direction abuts inside the concave portion 1a to be positioned and fixed.

A cylindrical insert 3 has a length similar to that of the insert material holding portion 2a and has a predetermined gradient in the longitudinal direction along the outer peripheral surface of the insert material holding portion 2a of the protective member 2. The insert material holding portion 2 of the protective member 2 is
a is positioned and fixed at a predetermined position in the concave portion 1a of the molding die 1 while being inserted and held from the inside. Reference numeral 4 denotes a molding resin molded from a thermosetting resin filled in a space between the concave portion 1a of the molding die 1 and the insert material 3, and is fixed to the outer peripheral surface of the insert material 3 so that the insert material 3 At the same time, a cylindrical resin molded product is formed.

In the conventional insert molding, first,
With the insert material 3 held from the inside by the insert material holding portion 2a of the protection member 2, the fixing portion 2 of the protection member 2
b is fitted into the hole 1b of the split mold 1B, the mold opening surfaces 1d of the split molds 1A and 1B are aligned, and the mold is closed, thereby positioning and fixing the protection member 2 in the concave portion 1a. Thereafter, as indicated by an arrow, the molten resin is press-fitted from outside the molding die 1 through a resin inflow passage 1c provided in the split mold 1A, and is filled between the concave portion 1a of the molding die 1 and the insert material 3. In this state, the molten resin in the concave portion 1a is hardened by heating to form the molding resin 4, and is fixed to the outer peripheral surface of the insert material 3 by contraction of the molding resin 4 due to cooling to form a cylindrical resin molded product. You. Thereafter, the split dies 1A and 1B are opened from the mold opening surface 1d, the fixing portion 2b is removed from the hole 1b, and then the insert material holding portion 2a of the protective member 2 is pulled out of the insert material 3 to release the mold. Is completed.

In the conventional insert molding method, when the molding resin 4 is injection-molded, the injection molding is performed while the inside of the insert material 3 is held by the protective member 2, so that the high temperature of the molten resin to be press-fitted is high. In addition, it is possible to prevent the insert material 3 from being damaged or deformed against high pressure. However, when the protective member 2 is released from the mold, since the molding resin 4 contracts due to cooling, the molding resin 4 tightens the protective member 2 via the insert material 3 and the insert material holding portion 2a is pulled out. Becomes difficult. Therefore, it is necessary to form the insert material holding portion 2a into a shape having a predetermined gradient.

[0007]

As described above, in the conventional insert molding, since the insert material holding portion 2a is tightened by the shrinkage of the molding resin 4, a predetermined gradient is applied to the insert material holding portion 2a of the protection member 2. It had to be provided. Therefore, when the insert material 3 fixed by the shrinkage of the molding resin 4 is required to have a shape without a gradient, the conventional insert molding method cannot be applied. For example, the molding resin 4 is used alone by machining, injection molding, extrusion molding or the like. After that, the insert material 3 is fixed to the molding resin 4, so that there is a problem that the addition of the fixed parts and the assembling time occur, and the processing cost increases. Further, when insert molding is performed without using a protective member, it is necessary to select a material for an insert material having a heat-resistant temperature and mechanical strength that can withstand the temperature and injection pressure of the molten resin at the time of injection molding.

SUMMARY OF THE INVENTION The present invention has been made to solve the above-mentioned problems, and it is possible to prevent the insert material from being deformed or damaged at the time of injection molding regardless of the resin strength and to cool the molded resin. An object of the present invention is to provide an insert molding method capable of easily and reliably releasing a later insert material.

[0009]

According to a first aspect of the present invention, there is provided an insert molding method, wherein an insert material protecting means for preventing deformation, breakage, etc. of the insert material is disposed inside the insert material. A coating layer having a low coefficient of friction is provided in advance outside the insert material protecting means or inside the insert material. Further, the insert molding method according to claim 2 is configured such that a material having a low coefficient of friction is provided inside the insert material,
An insert material protecting means for preventing deformation and breakage of the insert material is provided. In the insert molding method according to the third aspect, the insert material protecting means is brought into contact with the inside of the insert material in a state of being expanded by injecting a predetermined pressurized gas or liquid into the insert material protecting means. The resin is poured into a space between the outer periphery of the insert material and the inner periphery of the molding die, and after the resin is cured, the gas or liquid inside the insert material protection means is reduced by discharging the gas or liquid. is there. In the insert molding method according to a fourth aspect, a gas or liquid of a predetermined pressure is sealed inside the insert material as insert material protection means for preventing deformation, breakage, and the like of the insert material. 6. The insert molding method according to claim 5, wherein in the insert molding method, a pull-out means for pulling out the insert material protecting means is engaged with an engaging portion provided in advance in the insert material protecting means. The protection means is to be pulled out. 7. The insert molding method according to claim 6, wherein in the insert molding method, a resin filling portion provided in advance in the insert material is filled with a resin poured into a molding die, and a cylindrical body having a locking portion. Is formed. In the insert molding apparatus according to a seventh aspect, a coating layer having a low friction coefficient is provided outside the insert material protecting means or inside the insert material. Claim 8
In the insert molding apparatus described in (1), the insert material protecting means or the insert material is made of a material having a low coefficient of friction. In the insert molding apparatus according to claim 9, the insert material protecting means is expanded by injecting a predetermined pressurized gas or liquid into the inside to expand and abut against the inside of the insert material, and after the cylindrical body is formed, the gas or liquid is expanded. It is constituted by a bag body which is contracted and released by discharging the liquid. The insert molding device according to claim 10,
The insert material protecting means is constituted by a predetermined pressurized gas or liquid sealed in the insert material by a sealing means provided at a portion where the mold and the insert material are in contact with each other.

[0010]

DESCRIPTION OF THE PREFERRED EMBODIMENTS Embodiments of the present invention will be described below with reference to the drawings. In each of the drawings, the same components as those in the related art are denoted by the same reference numerals, and description thereof is omitted.

Embodiment 1 FIG. 1 is a sectional view showing an insert molding apparatus used in one embodiment of the present invention. In this figure, reference numeral 20A denotes an insert material protection member for protecting the insert material 30 from high temperature and high pressure during injection molding of a resin material. The insert material 30 has a cylindrical shape having a circular or square cross section in advance. A cylindrical or prismatic insert material holding portion 20a having the same length as the concave portion 1a of the mold 1 so as to extend along the entire inner peripheral surface.
And a split mold 1 provided at one end of the insert material holding portion 20a.
And a fixing portion 20b protruding so as to fit into the hole 1b provided in the hole B. Reference numeral 21 denotes a thin-film coating layer formed of Teflon or the like with a filler having a low friction coefficient, and is formed in advance on the entire outer periphery of the insert material holding portion 20a of the protection member 20A. The coating layer 21 has heat resistance to the high temperature of the molten resin press-fitted into the molding die. For example, when molding a cylindrical resin molded product attached to the tip of an antenna of a mobile phone, Teflon or the like is used. Will have a heat resistance of about 200 ° C.

In the present embodiment, the insert holding portion 20a of the protection member 20A is arranged inside the insert 30 via the coating layer 21, and the fixing portion 2b is held while the insert 30 is held from the inside. The protection member 20A is positioned and fixed in the concave portion 1a of the molding die 1 by fitting into the hole 1b provided in the division die 1B and closing the division dies 1A and 1B. In this state, the molten resin is press-fitted in the same manner as in the related art, and the molding resin 4 is heated and cured, and then the molding resin 4 is fixed to the outside of the insert material 30 by contraction of the molding resin due to cooling. Thereafter, at the time of release, the split dies 1A and 1B are opened, and the insert material holding portion 20a is pulled out from the insert material 30. In this case, the insert resin holding member 20a is shrunk by the cooling of the molding resin 4 via the insert material 30. Even when the insert material holding portion 20a is in a tightened state, the friction generated between the insert material holding portion 20a and the insert material 30 can be reduced by the coating layer 21 formed on the entire outer periphery of the insert material holding portion 20a. Material holding portion 20a from material 30
Can be easily pulled out.

As described above, according to the present embodiment, since the coating layer having a low friction coefficient is formed outside the insert material holding portion of the protective member, deformation and breakage of the insert material during injection molding are prevented. In addition, the mold release of the insert material after cooling the molding resin can be easily performed. In addition, since the insert layer has a coating layer, there is no need to provide a gradient in the insert material holding portion. Therefore, even when the insert material requires a shape without a gradient, the insert molding method can be applied. In the present embodiment, the coating layer is formed on the entire outer periphery of the insert material holding portion. However, if the release is easy, a coating layer formed on only a part of the coating layer may be used. . Also,
A material in which a coating layer is formed on the inner peripheral surface of the insert material may be used.

Embodiment 2 FIG. FIG. 2 is a view showing an insert molding apparatus used in another embodiment of the present invention. In the first embodiment, the coating member 21 is formed on the entire outer periphery of the insert material holding portion 20a of the protection member 20A. However, in the present embodiment, a material having good releasability that facilitates pulling out is used. For example, a protective member 20B constituted by an insert material holding portion 20a formed of a material having a low coefficient of friction such as a Teflon material containing a filler is used. Also in this case, the first embodiment
As in the case of the above, the mold 1 and the protective member 20B are released after the molding resin 4 is cooled. However, at the time of the release, the insert material holding portion 20a is tightened by contraction based on the cooling of the molding resin 4. Even in the case where the insert member 30 is in the inserted state, the friction generated between the insert member 30 and the insert member 30 can be reduced by forming the insert member holding portion 20a with a material having a low coefficient of friction. Pulling out the holding portion 20a becomes easy.

As described above, according to the present embodiment, since the insert material holding portion of the protection member is formed of a material having a low coefficient of friction, deformation of the insert material during injection molding can be reduced.
Breakage and the like can be prevented, and the mold release of the insert material after cooling of the molding resin can be easily performed. Further, since there is no need to provide a gradient in the insert material holding portion, the insert molding method can be applied even when the insert material requires a shape without a gradient. In the present embodiment,
Although the entire insert material holding portion is formed of a material having a good release property, only a part thereof may be formed of a material having a good release property, or the insert material itself may be made of a resin having a good release property. It may be formed of a material.

Embodiment 3 3 and 4 are cross-sectional views showing an insert molding device used in another embodiment of the present invention. In this figure, reference numeral 10 denotes a molding die, in which a cylindrical or prismatic concave portion 10a is formed inside similarly to the molding die 1, and is divided into a split die 10A and a split die 10B on a die opening surface 10d. The split mold 10A is provided with a resin inflow passage 10c similarly to the split mold 1A. The split mold 10B has a positioning holding portion 10e that protrudes from the longitudinal end surface in the concave portion 1a and is formed in an annular shape so as to hold a part of the inner peripheral surface of the insert material 30 by its outer peripheral surface. A through hole 10f is provided to extend from the inner peripheral surface to the outside of the mold. Reference numeral 22 denotes a protection member formed of an elastic member that can be expanded by injecting a gas or liquid into the inside. The protection member 22 is provided with a holding portion 10e.
The insert resin holding portion 22a of the bag body, which is arranged on the inner peripheral surface side of the insert material 30 held by the above and is expanded by injecting a gas or liquid at a predetermined pressure from the outside of the molding die and holds the insert material 30, A pipe 22b formed so as to communicate the insert material holding portion 22a with the outside of the molding die and inserted into the through hole 10f; And an opening 22c formed so as to be sealable by the stopping means.
The holding portion 10e is in a state where the insert material holding portion 22a of the protection member 22 is expanded (a state shown in FIG. 4).
What is necessary is just to be able to position and fix the insert material 30. In order to perform mold release, it is preferable that the portion holding the insert material 30 be as small as possible.

In this embodiment, first, the holding portion 10e provided in the concave portion 10a of the split mold 10B is
And is positioned by being inserted into, as shown in FIG.
Insert material holding portion 2 of protection member 22 inside insert
The split molds 10A and 10B are closed so that 2a is arranged. In this state, a gas or the like is injected from the opening 22c through the pipe 22b so that the insert material holding portion 22a has a predetermined pressure, and then the opening 22c is sealed, as shown in FIG. The insert material 30 can be held at a predetermined pressure from the inner peripheral surface side by the holding portion 10e and the insert material holding portion 22a. In this case, a gas or the like having a predetermined pressure that balances the molding pressure at the time of injection molding is injected into the insert material holding portion 22a.
For example, the air pressure when injecting gas is 60M
It is about Pa (600 kg / cm ² ). Note that a liquid may be injected as long as the condition (pressure of about 60 MPa) is satisfied. In this state, the molten resin is pressed into the space between the concave portion 10a of the molding die 10 and the insert material 30 as in the conventional case, and the molten resin in the concave portion 10a is heated and hardened. The molding resin 4 is fixed to the outside of the insert material 30 by contracting. Then, at the time of release, as shown in FIG.
The gas or the like sealed in the second insert material holding portion 22a is discharged from the opening portion 22c through the pipe portion 22b, and the insert material holding portion 22a is contracted. Thereby, even if the insert material 30 is in a state where the insert material holding portion 22a is tightened due to the shrinkage of the molding resin 4 due to the cooling of the molten resin, a gap can be provided in the space 30a of the insert material 30. The mold release can be easily performed by opening the mold 10A and the split mold 10B.

In this case, the insert 30 is
Although the holding portion 10e is in a tightened state, since the holding portion 10e holds only a part of the insert material 30, the insert material holding portion of the protection member is tightened by the entire inner peripheral surface of the insert material 30. In comparison with the case where the holding portion 10e is easily pulled out, and a coating layer having a low friction coefficient is formed on the outer peripheral surface of the holding portion 10e, or the holding portion 10e is formed of a material having a low friction coefficient. The release of the holding portion 10e can be facilitated.

As described above, in the present embodiment, by inserting gas or liquid into the insert material holding portion of the protective member, the insert material can be held under a predetermined pressure, and the insert material can be held at the time of injection molding. The deformation and breakage of the insert material can be prevented, and the mold and the like after cooling of the molding resin can be easily released by discharging gas and the like in the insert material holding portion at the time of release. Further, since there is no need to provide a gradient in the insert material holding portion, the insert molding method can be applied even when the insert material requires a shape without a gradient. In the present embodiment, a protective member having an opening disposed outside the mold through a tube is used. However, the present invention is not necessarily limited to this shape, and the opening is disposed in a concave portion of the mold. You may make it. In this case, before placing the insert material in the recess of the mold,
By arranging the insert material holding portion made of the bag body in advance after disposing it inside the insert material, the insert material is held from the inside and placed in the recess in this state, or the holding portion for positioning is provided. Before the split mold is closed in the state of being inserted into the insert material, the insert material holding portion is arranged inside the insert material and then expanded, thereby closing the split mold while holding the insert material from the inside. Furthermore, at the time of mold release, the mold is released by discharging gas or the like in the insert resin holding portion after opening the split mold.

Embodiment 4 FIG. 5 is a cross-sectional view showing an insert molding device used in another embodiment of the present invention.
Similarly, a cylindrical or prismatic concave portion 11a is formed inside, and is divided into a split mold 11A and a split mold 11B at a mold opening surface 11d. The split mold 11A has the same resin inflow path 1 as the split mold 1A.
1c is provided, and the split mold 11B has a holding section 1 having the same shape as the holding section 10e and the through hole 10f of the split mold 10B.
1e, a through hole 11f is provided. This through hole 11
In the present embodiment, f is a gas or liquid inflow path, and is sealed by a stopper or the like (not shown) provided on the concave portion 11a side or the opening on the outside of the molding die 11. The split mold 11A and the split mold 11B have respective end portions 3 of the insert material 30 at respective end faces in the longitudinal direction of the respective concave portions 11a, 11a.
An annular groove 11g is provided at a portion where 0b and 30b abut. Og as sealing means is provided in the groove 11g.
The ring 23 is fitted, and the depth thereof is formed to be slightly shallower than the cross-sectional diameter of the O-ring 23 so that the O-ring 23 slightly protrudes from the groove 11g. As a result, the insert material 3 positioned by the holding portion 11e
The O-rings 23, 23 come into close contact with the respective end portions 30b, 30b, thereby preventing gas or the like sealed in the space 30a from leaking into the concave portion 1a of the molding die 1.

In this embodiment, first, the insert material 3
0, the holding portion 11 provided in the concave portion 11a of the split mold 11B.
e to position the insert material 30
Then, as shown in FIG.
Split mold 11A so that O-ring 23 is in close contact
And the split mold 11B is closed. In this state, the route pon
Using a tool or the like, as shown by arrow X,
A gas or liquid at a predetermined pressure is introduced through the through hole 11f.
After injecting into the space 30a in the insert material, the through hole 11f
Is sealed, the holding portion 11e and the air of a predetermined pressure are sealed.
Holding the insert material 30 from the inner peripheral surface side
It becomes possible. In this case, the space in the insert material 30
30a has a predetermined value that balances the molding pressure during injection molding.
Injecting gas at pressure, etc.
The air pressure at the time of input is the same as in the third embodiment.
60MPa (600kg / cm ²) Degree. this
In the same state, press the molten resin in
After heating, hardening and cooling 4, split mold 11A and split mold 1
1B, the space 30a of the insert material 30 is opened.
The air at a predetermined pressure enclosed in the
Type can be done.

As described above, according to the present embodiment, air leakage is prevented by the O-ring as the sealing means, and air of a predetermined pressure is sealed in the space inside the insert material, so that the inner surface of the insert material is Since direct pressure is applied, deformation and breakage of the insert material during injection molding can be prevented without using a protective member having a holding portion for the bag body, and after the molding resin is cooled, the split mold 11 is not used.
By opening the split mold 11A and the split mold 11B, the mold release of the insert material can be easily performed. In addition, even when the insert material is required to have a shape without a gradient, the insert molding method can be applied. In this embodiment, air leakage is prevented by the O-ring. However, it is sufficient that gas can be sealed in the space in the insert material, and another sealing material may be used instead of the O-ring. Good. Further, the shape is not limited to the shape of the O-ring, but may be a flat plate that comes into contact with the end face of the insert material.

Embodiment 5 FIG. 6 is a view showing an insert molding apparatus used in another embodiment of the present invention. In this figure, reference numeral 20c denotes an insert material through an opening provided at the center of the end face of the fixing portion 20b of the protection member 20A. A screw hole as an engaging portion provided to extend inside the holding portion 20a. For example, a female screw to be screwed with a male screw formed at the tip of a tool as a drawing means (not shown) is provided as a screw hole. 20c is formed on the inner peripheral surface. In the present embodiment, after cooling the molding resin 4, the molding die 1 is removed,
When the protective member 20A is pulled out, a male screw formed at the tip of a drawing tool (not shown) is screwed into a female screw formed on the inner peripheral surface of the screw hole 20c, thereby performing a pulling operation using the drawing tool. I do. As described above, according to the present embodiment, since the screw hole for fitting the extraction tool to the fixing portion of the protection member is formed as the engagement portion for engaging the extraction means, by using the extraction tool,
The mold release of the insert material can be performed more easily and reliably. In the present embodiment, a screw hole as an engaging portion is provided on the end surface of the fixing portion of the insert material protecting member, but may be provided on the end surface of the holding portion. Also,
In the present embodiment, a case is described in which the protective member 20A having the coating layer 21 formed on the outer periphery is used. However, the protective member 20B made of a fluororesin or the like having a low friction coefficient described in the second embodiment is used. The same effect can be obtained by using.

Embodiment 6 FIG. FIG. 7 is a view showing an insert molding apparatus used in another embodiment of the present invention. In this figure, reference numeral 31 denotes a circular or square cylindrical shape which is formed in advance. This is an insert material into which the insert material holding portion 20a is inserted.
The holes 31c penetrating through 1 are arranged substantially linearly at predetermined intervals in the longitudinal direction. In this embodiment, an example in which two holes 31c are provided is shown. 4a is
Molded resin 4 filled in hole 31c as resin filling portion
Is a locking portion formed by a part of the. In the present embodiment, when the molten resin is press-fitted into the concave portion 1a, the hole 31c of the insert material 31 is also filled with the molten resin, and the locking portion 4a is formed by heating and hardening, and the locking portion 4a is formed. The molding resin 4 is fixed to the outside of the insert material 31 by the contraction. Also, the insert member 30 is formed by the locking portion 4a.
Is securely positioned and fixed inside the molding resin 4. Therefore, when the protective member 20 </ b> A is pulled out after the removal of the molding die 1 or when the insert material 31 is displaced after the completion of the resin molded product, etc. Thus, it is possible to easily and reliably perform the pulling-out operation, and it is possible to form a securely fixed resin molded product. As described above, according to the present embodiment, since the hole as the resin filling portion is provided in the insert material integrally formed with the molding resin by insert molding, the hole provided in the insert material is filled. A part of the molded resin that has functioned as a locking portion when the protective member is pulled out, etc. It is easy and reliable, and it is possible to form a securely fixed resin molded product. In the present embodiment, the protection member 20A according to the insert molding apparatus according to the first embodiment is used. However, the protection member according to the other embodiment or the gas sealed by the sealing means according to the present embodiment may be used. Such an insert material may be held. In this case, when a protective member having a bag holding portion or gas or the like sealed by a sealing means is used as the protective member, no deviation or the like occurs in the drawing operation, but the resin molded product of the cylindrical body is completed. The effect of preventing the displacement of the insert material later can be obtained.

In the present embodiment, an example in which two holes 31c are provided as resin filling portions is shown. However, if a part of the filled molding resin functions as a locking portion,
One or three or more holes may be provided, and the holes may be provided not only on a straight line but also at an oblique position or an opposing position. The shape of the resin-filled portion is not limited to a hole, but may be a cutout or a slit provided in the insert material. The insert material is not damaged or deformed by high temperature and high pressure during injection molding. Any size is acceptable. When this resin molded product is used for the tip of an antenna of a mobile phone or the like, a hole formed in advance for plating of an insert material used as a part of the antenna is replaced with a hole for forming a locking portion. It may be.

Embodiment 7 FIG. 8 is a diagram showing an insert molding apparatus used in another embodiment of the present invention, and FIGS. 8B and 8C are cross-sectional views taken along line AA of FIG. 8A. In the above first to sixth embodiments, the case where the molding resin is molded simultaneously with the circular or square cylindrical insert material has been described. However, if the resin is cylindrical, other shapes, for example, as shown in FIG. As shown in FIGS. 3 and 4C, even when the insert material 31 and the molding resin 4 are formed in a polygonal shape (hexagon in the figure) or in a shape protruding in four directions from the central portion, the above-described operation is performed. The insert molding methods according to the first to sixth aspects can be applied. In this case,
The recess 1a is formed corresponding to the cross-sectional shape of the insert material 31 and the molding resin 4, and the insert material holding portion 2 is formed.
The insert member 31 may be held by a protection member 20C having a polygonal cross section or a protection member 20D having a shape projecting in four directions from the center. As the protection members 20C and 20D, those in which the coating layer 21 is formed on the entire outer periphery of the insert material holding portion 20a as in the first embodiment may be used, or the insert material holding portion as in the second embodiment. 20a may be formed of a coating material having a low coefficient of friction. Further, as the insert material, an insert material 30 having no hole may be used. In addition, instead of the protection members 20C and 20D, insert molding may be performed using an insert molding method including a balloon-shaped protection member 22 or an O-ring 23 provided in a molding die. In this case, even when the insert material has a special shape, the concave portions 10a and 11a and the holding portion 10e or the holding portion 1 are adapted to the shape of the insert material.
By forming 1e, it is possible to hold a predetermined pressure from the inner peripheral side, so that it is possible to easily cope with insert molding of various shapes.

[0027]

According to the insert molding method of the first aspect of the present invention, when the insert material protecting means for preventing the insert material from being deformed or damaged is arranged inside the insert material, Since a coating layer having a low coefficient of friction is provided outside the insert material protecting means or inside the insert material, deformation and breakage of the insert material during injection molding can be prevented, and the insert material can be maintained even after cooling the molding resin. Can be easily performed, and the insert molding method can be applied even when the insert material is required to have a shape without a gradient. According to the insert molding method of the present invention, an insert material protecting means which is made of a material having a low friction coefficient and which prevents the insert material from being deformed or damaged is arranged inside the insert material. Therefore, it is possible to prevent deformation and breakage of the insert material during injection molding, and to easily release the insert material even after cooling the molding resin. Also, an insert molding method can be applied. According to the insert molding method according to the third aspect, the insert material protecting means is expanded inside the insert material protecting means by injecting a predetermined pressurized gas or liquid into the insert material protecting means. Abut, pouring resin into the space between the outer circumference of the insert material and the inner circumference of the mold,
After the resin has hardened, the gas or liquid inside the insert material protecting means is reduced by discharging the gas, so that the insert material can be prevented from being deformed or damaged at the time of injection molding, and can be inserted even after cooling the molded resin. The material can be easily released, and the insert molding method can be applied even when the insert material is required to have a shape with no gradient. According to the insert molding method of the fourth aspect, a predetermined pressurized gas or liquid is sealed inside the insert material as insert material protection means for preventing the insert material from being deformed or damaged. In addition to preventing deformation and breakage of the insert material, the insert material can be easily released even after cooling of the molding resin. Can be applied. According to the insert molding method of the fifth aspect, in the insert molding method, a pulling means for pulling out the insert material protecting means is engaged with an engaging portion provided in advance in the insert material protecting means. Since the insert material protecting means is drawn, the same effect as the insert molding method according to claim 1 or 2 can be obtained, and the work of pulling out the insert material protecting means can be performed more easily and reliably. . According to the insert molding method of the sixth aspect, in the insert molding method, the resin filling portion provided in advance in the insert material is filled with the resin poured into the molding die, and the locking portion is provided. Since the cylindrical body is molded, the same effect as the insert molding method according to any one of claims 1 to 5 can be obtained, and the work of pulling out the insert material protecting means can be performed more easily and reliably. It is possible to reliably prevent the displacement of the insert material after completion. According to the insert molding apparatus of the seventh aspect, since the coating layer having a low coefficient of friction is provided outside the insert material protecting means or inside the insert material, deformation and breakage of the insert material during injection molding. In addition to this, the insert material can be easily released even after the molding resin is cooled, and the insert molding method can be applied even when the insert material requires a shape having no gradient. According to the insert molding apparatus of claim 8, since the insert material protecting means or the insert material is made of a material having a low coefficient of friction, deformation and breakage of the insert material at the time of injection molding can be prevented and the molding resin can be prevented. The mold can be easily released even after the cooling, and the insert molding method can be applied even when the insert is required to have a shape with no gradient. According to the insert molding apparatus of the ninth aspect, the insert material protecting means expands by injecting a predetermined pressurized gas or liquid into the inside and abuts on the inside of the insert material, and after forming the cylindrical body, Since it is composed of a bag that is released and contracted by discharging gas or liquid, it can prevent the insert material from being deformed or damaged during injection molding and release the insert material even after cooling the molding resin. Can be easily performed, and the insert molding method can be applied even when the insert material requires a shape without a gradient. Claim 1
According to the insert molding apparatus described in No. 0, the insert material protecting means is constituted by a predetermined pressurized gas or liquid sealed in the insert material by the sealing means provided at a portion where the mold and the insert material abut. As a result, deformation and breakage of the insert material during injection molding can be prevented,
Even after the molding resin is cooled, the insert material can be easily released from the mold, and the insert molding method can be applied even when the insert material requires a shape having no gradient.

[Brief description of the drawings]

FIG. 1 is a cross-sectional view illustrating an insert molding apparatus according to an insert molding method according to a first embodiment of the present invention.

FIG. 2 is a sectional view showing an insert molding apparatus according to an insert molding method according to a second embodiment of the present invention.

FIG. 3 is a cross-sectional view showing an insert molding apparatus according to an insert molding method according to Embodiment 3 of the present invention.

FIG. 4 is a sectional view showing an insert molding apparatus according to an insert molding method according to Embodiment 3 of the present invention.

FIG. 5 is a sectional view showing an insert molding apparatus according to an insert molding method according to a fourth embodiment of the present invention.

FIG. 6 is a sectional view showing an insert molding apparatus according to an insert molding method according to a fifth embodiment of the present invention.

FIG. 7 is a sectional view showing an insert molding apparatus according to an insert molding method according to a sixth embodiment of the present invention.

FIG. 8 is a sectional view showing an insert molding apparatus according to an insert molding method according to a seventh embodiment of the present invention.

FIG. 9 is a sectional view showing an apparatus according to a conventional insert molding method.

[Explanation of symbols]

4a locking portion, 10e holding portion, 10f inflow path, 1
1, 11A, 11B Mold, 11a recess, 11c
Resin inflow path, 11d mold opening surface, 11e holding part, 11
f Through-hole, 11g Groove 20A, 20B, 20C, 20D Protective member, 20a
Insert material holding portion 20b Fixed portion, 20c screw hole, 22 protective member, 2
2a Insert material holding part 22b Tube part, 22c opening part, 21 coating layer, 23 O-ring 31b hole.

Claims (10)

[Claims] When an insert material is arranged in a molding die and an insert material protecting means for preventing deformation or breakage of the insert material is arranged inside the insert material, the insert material protecting means is preliminarily provided. After providing a coating layer having a low coefficient of friction on the outside of the insert material or on the inside of the insert material, the resin is poured into a space between the outer periphery of the insert material and the inner periphery of the molding die and cured to form a cylinder. Insert molding method for molding a body. 2. An insert material is arranged in a molding die, and an insert material protecting means made of a material having a low friction coefficient for preventing deformation and breakage of the insert material is arranged inside the insert material. Then, a resin is poured into a space between the outer periphery of the insert material and the inner periphery of the molding die and cured to form a cylindrical body. 3. An insert material is arranged in a molding die, and an insert material protecting means for preventing deformation, breakage, etc. of the insert material is arranged inside the insert material, and the insert material protecting means is provided inside the insert material protecting means. In a state of being inflated by injecting a predetermined pressure gas or liquid, the insert material protecting means is brought into contact with the inside of the insert material, and a space between the outer circumference of the insert material and the inner circumference of the mold. A resin is poured into the tube, and after the resin is cured, a gas or a liquid inside the insert material protecting means is discharged to reduce the size, thereby forming a cylindrical body. 4. An insert material is disposed in a molding die, and a predetermined pressurized gas or liquid is sealed inside the insert material as insert material protection means for preventing deformation, breakage, and the like of the insert material. An insert molding method for molding a cylindrical body by pouring a resin into a space between an outer periphery of the insert material and an inner periphery of a molding die and curing the resin. 5. The insert molding method according to claim 1, wherein a pulling-out means for pulling out the insert material protecting means is engaged with an engaging portion provided on the insert material protecting means in advance to pull out the insert material protecting means. The insert molding method according to claim 1 or 2, wherein: 6. The insert molding method according to claim 1, wherein a resin filled portion provided in advance in the insert material is filled with a resin poured into a molding die to form a cylinder having a locking portion. The insert molding method according to any one of claims 1 to 5, wherein 7. An insert material is arranged in a molding die, and an insert material protecting means for preventing deformation, breakage, etc. of the insert material is arranged inside the insert material. In an insert molding apparatus for casting a resin into a space between the inner periphery of the insert material and a cylindrical body, a coating layer having a low coefficient of friction is provided outside the insert material protecting means or inside the insert material. Features insert molding equipment. 8. An insert material is disposed in a molding die, and insert material protection means for preventing deformation, breakage, etc. of the insert material is disposed inside the insert material, and the outer periphery of the insert material and the molding die are arranged. In an insert molding apparatus for molding a cylindrical body by pouring a resin into a space between the insert material and an inner periphery of the insert material, the insert material protecting means or the insert material is made of a material having a low friction coefficient. apparatus. 9. An insert material is arranged in a molding die, and an insert material protecting means for preventing deformation, breakage and the like of the insert material is arranged inside the insert material. In an insert molding apparatus for molding a cylindrical body by pouring a resin into a space between the inner circumference of the insert material and the insert material, the insert material protecting means expands by injecting a predetermined pressurized gas or liquid into the inside to expand the insert material. An insert molding apparatus, comprising: a bag that abuts on the inside and is contracted and released by discharging the gas or liquid after molding the cylinder. 10. An insert material is disposed in a molding die, and insert material protection means for preventing deformation, breakage, etc. of the insert material is disposed inside the insert material, and the outer periphery of the insert material and the molding die are disposed. In an insert molding apparatus for molding a cylindrical body by pouring a resin into a space between the inner periphery of the insert and the insert, the mold is sealed in the insert material by a sealing means provided at a portion where the insert material abuts. An insert molding apparatus wherein an insert material protecting means is constituted by a gas or a liquid of a predetermined pressure.