JPS59127745A - Manufacture of vibration-proof member - Google Patents

Abstract

PURPOSE:To obtain an all-plastic vibration-proof member excellent in the heat resistance by a method wherein a polyether resin is molded in two cavities isolated concentrically and a specified resin composition is molded in a cavity arranged between these cavities so as to be put together. CONSTITUTION:First, a polyether resin 3 melted by heating is injected separately into a first die cavity 1 and a second die cavity 2 isolated concentrically. Then, a core 4 is retreated to open a third cavity 5 and a composition of 75-50wt% of a stylene-butadiene-stylene block copolymer resin and 25-50wt% of a stylene-ethylbutylene-stylene block copolymer resin melted by heating is injected thereinto. Then, after the die is cooled entirely down to the room temperature, it is opened to take out a vibration-proof member. The parts 10 and 11 of the vibration-proof member are hard and the part 12 thereof is soft.

Description

[Detailed description of the invention] (Technical field of invention) The present invention relates to a method of manufacturing a vibration isolator.

(Technical background of the invention and its problems) Conventionally, vibration isolating materials have been composed of metal parts arranged concentrically and molded parts of a rubber-like nydistomer fixed between the metal parts. Many things are used. To fully manufacture such a vibration damping material, the metal part coated with adhesive on the inner interface is placed in a mold, and the elastomer is completely injected between the n-ply and the entire part is heated to completely cure the elastomer. has been taken. However, with this method,
In addition to poor productivity and high manufacturing costs, there were problems in that it was difficult to set the molding temperature and pressure conditions for the elastomer to ensure complete adhesion between the metal and the nidistomer.

In order to solve all of these problems, polyether resin (hereinafter referred to as P, P.0 resin) was used instead of metal, and the inner and outer mold cavities were coated with this resin in a concentric manner and isolated from each other. A continuous manufacturing method for a vibration damping material in which both the hard part and the soft part are made of lastic material is proposed, in which both the hard part and the soft part are injection molded into the mold cavity, and then the entire part is injection molded between the mold cavities. There is.

However, in this method, the soft portion 1fr, the constituent S
, B, and S resins do not have sufficient heat resistance, so there is a problem that it is not possible to manufacture vibration damping materials with good characteristics.

(Purpose of the Invention) The present invention was made to solve these problems, and in particular, a method for efficiently manufacturing an all-plastic vibration damping side with excellent heat resistance by repeating a simple process. The entire purpose is to provide all.

(Summary of the Invention) The present invention provides a heating bath for melting P and P in concentric and mutually isolated first and second mold cavities.

0 resin is simultaneously injected to form a molded body, and before the resin slightly hardens and reaches maximum hardness, S is injected into a third mold cavity disposed between the first and second mold cavities. ,
75 to 50% by weight of B, S resin (hereinafter simply referred to as 0) and styrene-ethyl B, 8 resin. ) 25 to 50% of the composition is heated and melted, the whole is injected to form a molded body, and the first and second molded body parts and the third molded body part are directly joined. This is a method for manufacturing vibration isolating materials that has all the following characteristics.

In the present invention, S is injection molded into the third mold gap.
, B, S resin and composition consisting of S, E, B, S resin's, E-B, S'# fat is 25 to 50 inches, S
, B, and S resins are limited to a range of 75 to 50% for the following reason. That is S.

If the blending ratio of E, B, and 8 resins is less than 25% of the total composition and the ratio of S, B, and S resins exceeds 75%, the effect of improving the heat resistance of the third molded body portion is almost negligible. On the contrary, if the blending ratio of S, E, B, 54f1 fat exceeds 50%, 8.
If the deflection of B, S resin is less than 50%, P, P, 0
This is because the adhesive strength with the first and second molded body parts made of resin is insufficient and it cannot be put to practical use.

(Example of the invention) Examples of the present invention will be described below.

Example 1 Into a first mold cavity 1 and a second mold cavity 2 which are concentrically separated from each other as shown in FIG. After injecting P.0 resin 3= at a maximum of 70 kg/cr/b for 11 seconds at a high pressure and then at a low pressure of 10/cg/7 for 6 seconds, 1 second later the core 4 was injected as shown in Figure 2. The third mold cavity 5 is opened by retracting the mold cavity at a position of about 200 degrees.
S heated to C and melted.

A composition consisting of 25% of E, B, 8 resin and 75% of S, B, 8 resin was subjected to high pressure of maximum 85#I/cII for 13 seconds.
Then, a low pressure of xolv;1/cl was injected for 5 seconds. Next, the entire mold was cooled down to room temperature, the mold was completely opened, and the vibration isolating material shown in FIG. 3 was taken out. Codes 10 and 1 of this vibration isolating material
The part 1 is a hard part, and the part 12 is a soft part.

The adhesive strength between the first and second molded body parts and the third molded body part of the obtained vibration damping material was measured using an autograph tester, and a value of 73 kg was obtained. This value was much larger than the maximum allowable load of the vibration damping material, 1 g lcg.

Example 2 50 pieces of S, E, B, S resin and S were placed in the third mold cavity.
A vibration damping material was produced in exactly the same manner as in Example 1, except that the entire composition was injection molded. The result of measuring the adhesive strength between the first and second molded body parts and the third molded body part of the obtained vibration isolating material in the same manner as in Example 1 was 60.
After obtaining the value of kg, the heat resistance of the third molded body portion of the vibration isolating material 1 manufactured in Example 1 and Example 2 was examined. Heat resistance was determined by applying a static line load of 10 kg to the vibration damping material at different temperatures and measuring the amount of displacement at regular intervals.

The measurement results are shown in the table below.

In addition, those listed as comparative examples in the table are conventional S.

The heat resistance of a vibration damping material molded from 100 pieces of B and S resins was measured in the same manner.

Margin below (Effects of the Invention) As is clear from the above examples, according to the present invention, the heat resistance of the soft part is improved in distance.In addition, all plastics with high adhesive strength between the soft part and the hard part. It is possible to manufacture vibration-proofing materials efficiently.

[Brief explanation of drawings]

The drawings are sectional views for explaining the present invention in detail. 3 ・・・・・・・・・ P, P.
0 I Inquiry Month 4・・・・・・・・・Core Representative Patent Attorney Yama 1) Shin Akira Figure 1 Figure 2 Figure 3 Figure 1 Display of the case 1982 Patent Application No. 3236 Bureau 2 Name of the invention Relationship with the person making the amendment to the manufacturing method of vibration-proofing material 3 Patent applicant: 2-1-1 Oda Sakae, Kawasaki-ku, Kawasaki City (225) Showa Electric Wire and Wire Co., Ltd. Representative: Minoru Yoshihiko, 4th generation, Kawasaki City 2-1-1-6 Oda Sakae, Kawasaki-ku A column for a brief explanation of the drawings of the specification subject to amendment. 7. The statement of contents of the amendment, page 8, lines 7-8, “The drawings are...
It is. ” is corrected to read as follows. "Figures 1 and 2 are sectional views for explaining the present invention in detail, and Figure 3 is a sectional view showing a vibration isolating material obtained by the method of the present invention. 1 or more

Claims (1)

[Claims] 1. Polyether resin heated and melted is simultaneously injected into the first and second mold cavities that are concentric and isolated from each other to form a molded body, and the resin hardens slightly until it reaches its maximum hardness. Before reaching the temperature, the composition consisting of the first and second mold cavities is completely heated and melted and injected to form a molded body, which is then molded within the first and second mold cavities. A method for manufacturing a vibration isolating material, which comprises directly joining the first and second molded body parts and the third molded body part in their entirety.