JPH06315943A - Integral skin foam molding method and polyurethane molding material - Google Patents

Abstract

PURPOSE:To reduce a material loss by forming a fluorocarbon-free, low-foam, and dense self-skin layer having little residual foam and eliminating the need for an overpack of a polyurethane material. CONSTITUTION:A pressure of a cavity 4 of a mold 1 is reduced to 50-400 Torr. A polyurethane material M mainly composed of a polyol component and an isocyanate component is prepared by adding no fluorocarbon, a water/isocyanate reaction catalyst, and 0.1-0.6 pts.wt. water per 100 pts.wt. of polyol component. The polyurethane material M is injected into the cavity 4 and foamed. In this manner, a semi-cured ISF provided with a low-foam self-skin layer and a high- foam core part is molded.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a method for molding a semi-rigid integral skin foam having a low-foaming self-skin layer and a highly-foaming core part, for example, a coating or a pad for a steering wheel of an automobile. Instrument panel, lid for console box and glove box,
IS such as headrest, armrest, air spoiler
The F molded product is reaction injection molded (hereinafter referred to as RIM molding).
It is suitable for

[0002]

2. Description of the Related Art A low-foam self-skin layer is provided on the surface,
A semi-rigid polyurethane foam having a highly foamed core part inside is generally an integral skin foam (hereinafter referred to as I
It is called SF. ) Called. Conventionally, this ISF is formed by injecting a polyurethane material containing a polyol component and an isocyanate component as main components and adding freon into a cavity of a mold, and volatilizing and foaming the freon by heat of urethane reaction.

Inside the polyurethane material away from the mold surface, reaction curing and volatilization of freon proceed at the same time, and innumerable bubbles are retained, so that a highly foamed core portion is formed.
Also, in the surface part of the polyurethane material in contact with the mold surface,
Since the reaction heat escapes to the mold and is cooled, the urethane reaction is relatively delayed as compared with the inside, and the calorific value is reduced. Therefore, volatilization of freon is suppressed, and only a small number of bubbles are generated. Moreover, the bubbles are crushed and reduced by the foaming pressure from the inside. Therefore, a low-foaming self-skin layer is formed on this surface portion.

[0004]

However, the method of molding an ISF by the above freon foaming has the following problems. (1) The use of CFCs is being banned or restricted because they cause ozone layer depletion and global warming when released to the atmosphere. Therefore, from the standpoint of improving the global environment, the development of an ISF molding method that does not use CFC has been awaited.

(2) Since the self-skin layer was formed by crushing the bubbles on the surface portion with the foaming pressure from the inside, minute bubbles inevitably remained on the self-skin layer, which appeared on the surface. Could damage the appearance.

(3) In order to increase the foaming pressure to facilitate the formation of the self-skin layer, and to prevent the material wraparound failure and the air discharge failure, the polyurethane material is overpacked in the cavity and a large amount of excess material is left over. Since the polyurethane material was blown out from the vent part, the material loss was large.

(4) Further, when a core metal is placed in the cavity and freon foaming is performed, turbulent flow occurs in the polyurethane material due to the core metal, and air is entrapped to cause pinholes, voids,
Defects such as lack of meat were likely to occur. This problem was particularly noticeable when a long core metal was placed in the cavity, such as the core metal of the ring portion of the steering wheel. Therefore, it is necessary to provide the gate at a position where turbulent flow is unlikely to occur, or to provide vents at a plurality of positions in order to discharge the trapped air.

Therefore, the present applicant has previously filed a patent application for a new method for molding an ISF without using CFCs (Japanese Patent Laid-Open No. 4-226313). The method comprises the steps of lowering the air pressure in the cavity of the mold, and injecting into the cavity a polyurethane material obtained by adding 0.1 to 0.6 parts by weight of water to 100 parts by weight of the polyol component to foam. And a step of filling and filling the same. The degree of vacuum (vacuum degree) of the cavity is preferably 100 Torr or less when the amount of water added is 0.1 parts by weight, and the amount of water added is 0.
It has been said that 400 Torr or less is preferable when the amount is 6 parts by weight.

In the above-mentioned new method, if the amount of water added and the degree of vacuum of the cavity are adjusted, the foaming ratio changes, so that ISFs having core portions having different densities could be molded. However, since the amount of water added was as small as 0.1 to 0.6 part by weight, it was difficult to mold the ISF having a high expansion ratio and a low-density core. Therefore, the inventors of the present invention have found that, even if the amount of water added is small, the present inventors can easily form an ISF having a high expansion ratio and a low-density core by promoting the water-isocyanate reaction. The present invention has been completed and the present invention has been completed.

Accordingly, a first object of the present invention is to provide a core portion having a high expansion ratio and a low density without using CFC.
It is to enable SF molding and contribute to the improvement of the global environment. The second object is to form a low-foaming dense self-skin layer in which almost no bubbles remain, and to obtain an excellent appearance and feel equivalent to or better than those in the case of freon foaming. A third object is to make defects such as pinholes, voids, and underfills less likely to occur, eliminate the need for overpacking of polyurethane material, and reduce material loss.

By the way, the following gazettes ~ describe the technology for producing polyurethane foam using reduced pressure, but none of these technologies disclose or suggest the object, constitution and effect of the present invention. JP-A-55-63237 and JP-A-55-63.
Japanese Patent No. 238 discloses a method in which a polyurethane material is uniformly foamed to every corner of a molding die by evacuation from pore grooves formed in the molding die. However, this publication makes no mention of a foaming agent.

Japanese Unexamined Patent Publication (Kokai) No. 56-111648 discloses a method of foaming a polyurethane material under a reduced pressure atmosphere, and one of its effects is that the amount of a foaming agent such as CFC can be reduced. . However, this method is still different from the present invention that does not rely on CFCs at all, because it still utilizes foaming with CFCs.

JP-A-62-164709 discloses a method for producing a low-density polyurethane foam by foaming a polyurethane material containing water as a foaming agent under a reduced pressure atmosphere. But this method
Instead of molding the ISF, the formation of the skin layer is evaluated as deterioration of the surface properties.

Japanese Patent Laid-Open No. 63-268624 discloses a polyurethane material containing nitrogen gas or the like in a volume ratio of 2 to 30.
%, And expand and foam in a reduced pressure atmosphere. However, this method also does not mold the ISF.

Japanese Examined Patent Publication No. 64-5528 discloses that a hard polyurethane material is packed in a depressurized mold with a pack ratio of about 150.
A method of pouring at ~ 450% to foam is disclosed. However, the rigid polyurethane material contains a foaming agent such as CFC.

[0016]

Therefore, according to the present invention, in a method of molding a semi-hard ISF having a low-foaming self-skin layer and a highly-foaming core portion, the mold cavity is depressurized to over 50 to 400 Torr. And the main component is a polyol component and an isocyanate component, CFC is not added, water / isocyanate reaction catalyst is added, and 0.1 to 0.6 parts by weight of water is added to 100 parts by weight of the polyol component. The step of injecting the resulting polyurethane material into the cavity for foaming.

Examples of the water / isocyanate reaction catalyst include aliphatic amines such as triethylamine and N, N-dimethylethanolamine. These may be added alone or in admixture of two or more. You can The amount of the water / isocyanate reaction catalyst added varies depending on the type and the required expansion ratio of the core portion, etc., but is usually 0.5 to 5 per 5 parts by weight of the polyol component.
0 parts by weight. In addition, the amount of water added (0.1 to 0.6 part by weight) is the amount of water naturally absorbed by the material (usually 0.1 to 0.6 parts by weight).
0.15 parts by weight).

[0018]

In the present invention, when the polyurethane material is injected into the cavity, the polyurethane material undergoes the following changes depending on the site.

First, the inside of the polyurethane material separated from the mold surface is sufficiently foamed by the following foaming action by water and its expanding and accelerating actions to form a core portion having a high expansion ratio and a low density.

Chemical foaming by chemical reaction of water In the interior of the polyurethane material, the urethane reaction between the polyol component and the isocyanate component proceeds and the temperature of the reaction heats up (for example, 70 to 90 ° C.). Reaction is also accelerated and CO ₂ is generated,
The polyurethane material foams. Further, since the cavity is depressurized, the generated CO ₂ expands according to Boyle-Charles' law. On the other hand, when the urethane reaction proceeds, the curing of the polyurethane material also proceeds, so that foaming is suppressed.

Therefore, the core portion is formed by a balance between foaming and curing of the polyurethane material. Generally, it is the amount of water added and the degree of vacuum of the cavity that contribute to foaming, and the catalyst that contributes to curing is the catalyst. The types and the amounts added.

In the present invention, the amount of water added is 0.1 to 0.6.
Since it is a small amount by weight, the amount of CO ₂ generated will decrease as it is. However, in the present invention, since the water / isocyanate reaction catalyst is added to the polyurethane material, CO
₂ occurs in large quantities and expands. Therefore, the inside of the polyurethane material becomes a core portion having a high expansion ratio and a low density. The expansion ratio can be changed by appropriately changing the amount of water added, the degree of vacuum of the cavity, the type and addition amount of the water / isocyanate reaction catalyst within the above range.

Physical Foaming by Boiling and Evaporating Water When the cavity is depressurized, the boiling point of water drops. Also,
The temperature inside the polyurethane material increases as described above. Therefore, the temperature inside the polyurethane material can be made higher than the boiling point of water by making the atmospheric pressure of the cavity particularly low or the temperature of the polyurethane material particularly high. In that case, the water boils and evaporates,
In addition to the chemical foaming, the vaporized water vapor also contributes to the foaming of the core portion.

Next, in the surface portion of the polyurethane material in contact with the mold surface, the heat of reaction between the polyol component and the isocyanate component escapes to the mold, and the temperature of the surface portion is the mold temperature (usually 40 to 60). Since the temperature does not rise above the temperature above 0 ° C), the reaction between water and the isocyanate component does not proceed and CO ₂
Rarely occurs. Further, since the cavity is depressurized, CO ₂ is not generated especially on the surface of the polyurethane material.
Is easily defoamed. Therefore, this surface portion becomes a low-foaming skin layer, and only very small bubbles that do not pose a problem appear on the surface. Therefore, it is possible to obtain an excellent appearance equivalent to or better than that of the conventional freon foaming.

Further, since the air is thinned in the cavity due to the reduced pressure, defects such as pinholes, voids, and wall thickness are less likely to occur. Therefore, it is not necessary to over-pack the polyurethane material as in CFC foaming, and material loss can be reduced.

[0026]

EXAMPLE A first example in which the present invention is embodied in forming an ISF coating for a steering wheel will be described with reference to FIGS. First, as shown in FIGS. 1 to 3, the molding apparatus used in this embodiment includes a molding die 1 including two split dies and a vacuum box 11 in which the molding die 1 can be arranged. And a vacuum pump 2 for vacuuming the inside of the vacuum box 11.
0, and a material injection mechanism 2 attached to the vacuum box 11 and capable of injecting a polyurethane material into the cavity 4 of the molding die 1.
1 and 1. Further, the core metal 42 of the steering wheel 41 used in the present embodiment is composed of a ring portion, a spoke portion, and a central boss portion, and the ISF coating 43 is formed on the entire ring portion and a part of the spoke portion. It

The molding die 1 is composed of two divided dies, an upper fixed die 2 and a lower movable die 3, and the facing surfaces of the two dies 2 and 3 are substantially ring-shaped cavities 4 when the dies are closed. Forming groove 4a is formed. At the center of the cross section of the cavity 4, the entire ring portion of the cored bar 42 and a part of the spoke portion are arranged. PL surfaces 2a, 3a of the fixed die 2 and the movable die 3
A sprue 6, which is a material flow path to the cavity 4, a runner 7, and a gate 8 are recessed in the groove, and the gate 8 is opened at the outer peripheral side of the molding groove 4a and at the left end in FIG. Therefore, the polyurethane material M is injected from the gate 8 into the cavity 4 and divided into two directions to flow, as shown in FIG.
At the final filling position L at the right end of the line, etc., they meet and fill.

A vent hole 5 is provided in the fixed mold 2 at the final filling position L. The diameter of the vent hole 5 is usually 1 to 10 mm. With the vent hole 5 having a diameter of less than 1 mm, when the final filling position L varies, the degassing effect may not be sufficiently obtained.
Vent holes 5 exceeding 5 are not preferable because the traces of the vent holes 5 are conspicuous after the finish processing of the molded product, which deteriorates the appearance of the molded product. In this embodiment, the diameter is 3 mm,
A straight vent hole 5 having a length of 15 mm was used. In addition, between the PL surfaces 2a and 3a when the mold is closed, 0.03 to 0.06 m is provided over the entire circumference of the cavity 4 due to the processing accuracy of the mold.
Although a gap of m is generated, this gap acts as an air vent land and has a function of degassing described later.

Inside the molding grooves 4a of the fixed mold 2 and the movable mold 3, a positioning fitting portion 31 for closing the molds 2 and 3 is formed.
And a recess 32 for accommodating and holding the boss portion of the cored bar 42.
And a pedestal 33 are provided. An ejector pin 34 for releasing the molded steering wheel 41 from the pedestal 33 is provided so as to project therefrom.

Since the molding die 1 is not required to have a very high pressure resistance (the foaming pressure is usually about 50 to 500 kPa), an inexpensive die such as an aluminum die or an electroforming die can be used. .

The vacuum box 11 is composed of an upper case 12 to which the fixed die 2 is fixed and a lower case 13 to which the movable die 3 is fixed, and the mounting groove provided at the mating portion of the upper case 12 is O-shaped.
A ring-shaped seal member 14 is mounted so that when the vacuum box 11 is closed, the inside thereof is sealed.
Further, as shown in FIGS. 1 to 3, a vacuum pump 20 is connected to a suction nozzle 16 provided in the lower case 13 via a suction hose 15 and a leak valve 17.
In this vacuum box 11, the molding die 1 can be arranged,
Moreover, it is formed in such a size that a space portion K is formed between the molding die 1.

As shown in FIGS. 5 and 6, the lower case 13 of the vacuum box 11 is provided with a see-through window 51 through which the vicinity of the vent hole 5 can be viewed from the outside of the lower case 13. The transparent window 51 has an opening 52 formed through the lower case 13.
And the seal ring 5 so as to close the opening 52 from the inside.
3 is composed of a transparent plate 54 made of glass or synthetic resin, which is applied to the inner surface of the lower case 13 through 3, and a frame 56 which holds the peripheral edge of the transparent plate 54 and is fixed to the lower case 13 by bolts 55. It A seal plate 57 is provided between the frame body 56 and the transparent plate 54 and between the frame body 54 and the lower case 13.
Is preferred.

Fixed mold 2 and upper case 12, and movable mold 3
The lower case 13 and the lower case 13 are integrated. The lower case 13 is attached to a hydraulic cylinder ram (not shown) or the like, and when the mold is closed, its peripheral edge matching portion is raised until it contacts the peripheral edge matching portion of the upper case 12, and is lowered when the mold is opened.

The material injection mechanism 21, as shown in FIG.
A tank 25 for storing a polyol mixed component, a tank 26 for storing an isocyanate component, and a mixing head 2
2 are connected to each other by a circulation path 29 equipped with a high-pressure pump 27 and a filter 28, respectively, and collision mixing of the polyol mixing component and the isocyanate component and circulation of each component can be repeated. Figure 1
And the like, the injection nozzle 2 of the mixing head 22
3 can be connected to the sprue 6 portion of the molding die 1 via the O-rings 24, 24.

The polyurethane material used in this example is
With a polyol component and an isocyanate component as the main components,
CFC-free, water-isocyanate reaction catalyst was added, and water was added to 0.1 parts with respect to 100 parts by weight of the polyol component.
.About.0.6 part by weight is added.

Next, the molding method of this embodiment will be described in the order of steps. With the molding die 1 opened as shown in FIG. 1, the cored bar 42 is set on the movable die 3 as shown in FIG.

As shown in FIG. 4, when the molding die 1 is closed to form the cavity 4, the vacuum box 1
1 is closed and the inside is sealed. In this embodiment,
By raising the lower case 13 by a hydraulic cylinder ram (not shown) or the like, the seal member 14 is brought into contact with the mating portion of the upper case 12 to close the vacuum box 11, and the fixed die 2 and the movable die 3 are separated from each other. I closed the mold. The opening / closing of the molding die 1 and the opening / closing of the vacuum box 11 can be performed individually by different hydraulic cylinders or the like, and the opening / closing timings of both can be shifted.

The vacuum pump 20 is actuated, and the space K of the vacuum box 11 from the suction nozzle 16 exceeds 50 to 400 To.
Depressurize to rr vacuum. At this time, the cavity 4
Is in communication with the space K of the vacuum box 11 through the gap between the PL surfaces 2a and 3a, the material flow path such as the sprue 6, and the vent hole 5, so that the cavity 4 is also approximately the same as the space K. The pressure is reduced to the degree of vacuum.

While continuously depressurizing the cavity 4, as shown in FIG. 4, the polyurethane material M is injected from the injection nozzle 23 into the cavity 4 to perform RIM.
Perform molding.

At this time, inside the polyurethane material M separated from the mold surface and the cored bar 42, due to the above-mentioned action,
As shown in FIG. 8, the core portion 45 having a high expansion ratio and a low density is formed. Further, on the surface portion of the polyurethane material M which is in contact with the mold surface, the low foaming dense self-skin layer 44 in which almost no bubbles remain is formed by the above-mentioned action. In addition, the same effect is applied to the inner surface portion of the polyurethane material M which is in contact with the cored bar 42, by the same action, and the dense self-adhesive layer 47 with low foaming
Is formed. Generally, the self-adhesive layer 47 is formed slightly thinner than the self-skin layer 44.

As the polyurethane material M flows, the gap between the PL surfaces 2a and 3a self-seals in order. Then, when the flow front end of the polyurethane material M reaches the final filling position L and blows out a little from the vent hole 5, the flow front end reacts and cures so that the vent hole 5 is self-sealed. The reaction speed of is adjusted.

In this embodiment, as shown in FIG.
Since the vicinity of the vent hole 5 can be visually observed from the outside of the vacuum box 11 through the transparent window 51, the flow front end of the polyurethane material M can be changed to the vent hole 5 while the vacuum box 11 is sealed.
It is possible to confirm that it is blown out from the container and to observe its foaming state.

As a side effect of decompressing the cavity 4, the air obstructing the flow of the polyurethane material M becomes thin, so that even if the cavity 4 has an undercut portion or a branch portion, the polyurethane material M will not Make sure to wrap around the area. Further, the degassed stored gas is sucked and discharged from the gap between the vent hole 5 and the PL surfaces 2a and 3a. Therefore, unlike the freon foaming, it is not necessary to overpack the polyurethane material, and the material loss can be reduced.

After the polyurethane material M is cured, the molding die 1 is opened and the vacuum box 11 is opened, as shown in FIG. In conjunction with this mold opening, the eject pin 34 of the movable mold 3 projects, and the molded steering wheel 41 with the ISF coating 43 is automatically released.

According to the molding method and the polyurethane material of the present embodiment as described above, particularly the steering wheel 41 is used.
The following effects (a) suitable for molding the ISF coating 43 of
(b) and (c) are also obtained.

(A) The polyurethane material M easily causes turbulence due to the long ring portion of the cored bar 42. However, since air is thinned in the cavity 4 of the present embodiment due to the reduced pressure, defects such as pinholes, voids, and wall thickness are less likely to occur.
Therefore, the degree of freedom of the position of the gate 8 is increased by providing the gate 8 on the outer peripheral side of the ring portion as in the present embodiment. Moreover, one vent hole 5 is sufficient.

(B) As described above, since the polyurethane material M flows in the cavity 4 in two directions and joins at the final filling position L, generally, a weld line is apt to occur at the joining portion, or a pin is formed. There is a peculiar problem that gas that causes holes, voids, lack of wall, etc. tends to accumulate.
However, in this embodiment, since the cavity 4 is depressurized and the flow front end of the merging portion is blown out from the vent hole 5, these defects can be surely prevented.

(C) In this embodiment, since the dense self-adhesive layer 47 in which almost no bubbles remain is formed on the inner surface of the ISF coating 43, the ISF coating 4 on the ring portion of the cored bar 42 is formed.
The holding power of 3 becomes stronger.

In order to confirm the effect of this embodiment, Table 1
As shown in, a polyurethane material having each composition of Test Example 1 and Test Example 2 included in the category of this example and Comparative Examples not included in the category was prepared. The polyether polyol used is a bifunctional polyether polyol (molecular weight 4
000) and trifunctional polyether polyol (molecular weight 60
00) and the same amount. Triethylenediamine is a catalyst that has been conventionally added and promotes both foaming and curing. Usually, 0.6 to 1.0 part by weight is added to 100 parts by weight of the polyol component. In addition to the same catalyst, triethylamine was added as a water / isocyanate reaction catalyst to Test Example 1, and N, N-dimethylethanolamine was also added to Test Example 2.
On the other hand, no water / isocyanate reaction catalyst was added to the comparative example. Then, each polyurethane material was injected into the cavity 4 of each vacuum degree shown in Table 1 and foamed to form the ISF coating 43 of the steering wheel.

[0050]

[Table 1]

Core part of ISF coating 43 molded in this way
When the density of 45 was measured, as shown in Table 1,
Comparative example is 0.7 g / cm³ However, the test example 1
Is 0.4 g / cm³ , Test Example 2 is 0.5 g / cm³ And
Both have high expansion ratio and low density I was there. Also,
Test example 1 and 2 There are almost no bubbles on the surface of the skin layer 44.
It does not appear, but is as good as or better than the case of freon foam
The appearance and feel were obtained.

Next, the present invention is applied to the steering wheel I.
A second embodiment embodied in forming the SF pad will be described with reference to FIGS. The molding apparatus used in this embodiment has a lower case 13 in which a cavity 4 for molding an ISF pad is formed between a molding concave portion provided in the movable mold 3 and a molding convex portion provided in the fixed mold 2. The difference from the first embodiment lies only in that the seal member 14 is attached to the mating portion. Therefore, the members common to the first embodiment,
The same reference numerals as those in the first embodiment are attached to the same figure to avoid redundant description.

As in the first embodiment, the polyol component and the isocyanate component were the main components, no CFCs were added, the water / isocyanate reaction catalyst was added, and water was added to 0.1 parts by weight of water per 100 parts by weight of the polyol component. ˜0.6 parts by weight of the polyurethane material M added, more than 50 to 400 Torr
Then, the resin is injected into the cavity 4 depressurized to the vacuum degree, and RIM molding is performed. At this time, as shown in FIG. 12, a core portion 38 having a particularly high expansion ratio is formed inside the polyurethane material M away from the mold surface, and almost all bubbles remain on the surface portion of the polyurethane material M in contact with the mold surface. A low-foaming, dense self-skin layer 39 is formed, and the ISF pad 37 excellent in appearance and physical properties is thereby formed.

Also in this second embodiment, the same effects as in the first embodiment can be obtained except for the effects peculiar to the ISF coating 43.

The present invention is not limited to the configuration of the above-described embodiment, and may be embodied by being arbitrarily modified within the scope not departing from the spirit of the invention as follows. (1) In the embodiment, the molding die 1 and the vacuum box 11 are shown as separate bodies, but the molding die has a double wall structure and the outer wall has the same function as the vacuum box 11. In this way, the space portion may be integrally provided in the molding die.

(2) As shown in FIG. 13, a molding die 1
If a large groove-shaped recess 9 capable of depressurizing the inside of the cavity 4 can be formed over the entire circumference or part of the outer circumference of the cavity 4, the groove-shaped recess 9 functions as a space. The groove-shaped recess 9 can be formed in one or both of the movable die 3 and the fixed die 2 of the molding die 1. In addition, it is preferable to provide a seal member 10 on the outer periphery of the groove-shaped recess 9 for blocking outside air.

(3) In the above embodiment, the vent hole 5 is provided, but instead of the vent hole 5, fine pores are provided facing the cavity and at the final filling portion of the polyurethane material. The molding method of the present invention may be carried out by using a mold using a core having the above-mentioned structure to allow the final degassing from the fine pores.

(4) The mold to be used is not limited to the mold, and various molds such as ceramic mold, resin mold and the like which can withstand the foaming pressure can be used.

[0059]

The ISF molding method of the present invention has the following excellent effects. ISF with a high expansion ratio and a low density core can be molded without using CFCs, which contributes to the improvement of the global environment. It is possible to form a low-foaming, dense self-skin layer in which almost no bubbles remain, and to obtain an excellent appearance and feel equivalent to or better than those in the case of freon foaming. Since air is diluted in the cavity due to decompression, defects such as pinholes, voids, and wall thickness are less likely to occur. Therefore, it is not necessary to over-pack the polyurethane material as in CFC foaming, and material loss can be reduced.

[Brief description of drawings]

FIG. 1 is a cross-sectional view when a molding die and a vacuum box used for RIM molding of an ISF coating of a steering wheel of a first embodiment are opened.

FIG. 2 is a plan view of a movable die of the molding die and a lower case of a vacuum box.

FIG. 3 is a schematic view of a material injection mechanism used for the molding.

FIG. 4 is a cross-sectional view when RIM molding is performed with the molding die and vacuum box closed.

5 is a side view of FIG. 4 showing a see-through window.

FIG. 6 is a partially enlarged sectional view of FIG. 4 showing the transparent window.

FIG. 7 is a cross-sectional view when the molding die and the vacuum box are opened and the ISF coating is released.

FIG. 8 is a partially enlarged sectional view of the same ISF coating.

FIG. 9 is a cross-sectional view when a molding die used for RIM molding of a steering wheel ISF pad and a vacuum box of the second embodiment are opened.

FIG. 10 is a cross-sectional view when RIM molding is performed with the molding die and vacuum box closed.

11 is a sectional view taken along line XI-XI of FIG.

FIG. 12 is a partially enlarged sectional view of a molded ISF pad.

FIG. 13 is a cross-sectional view showing another example of the molding die.

[Explanation of symbols]

DESCRIPTION OF SYMBOLS 1 Molding die 2 Fixed type 3 Movable type 4 Cavity 11 Vacuum box 12 Upper case 13 Lower case 20 Vacuum pump 37 ISF pad 38 Core part 39 Self-skin layer 41 Steering wheel 42 Core metal 43 ISF coating 44 Self-skin layer 45 core Part M Polyurethane material

 ─────────────────────────────────────────────────── ─── Continuation of the front page (72) Inventor Yukio Kawakita 1 Ochiai, Nagachi, Kasuga-cho, Nishikasugai-gun, Aichi Toyoda Gosei Co., Ltd. Address: Toyoda Gosei Co., Ltd. (72) Inventor, Michihiko Nakamura, Kasuga Town, Nishikasugai-gun, Aichi Ochiai, Nagahata 1

Claims (1)

[Claims] 1. A method for molding a semi-rigid integral skin foam having a low-foaming self-skin layer and a highly-foaming core part, wherein a mold cavity has a cavity of more than 50 to 400 Tor.
a step of reducing the pressure to r, a polyol component and an isocyanate component as main components, no CFCs added, a water / isocyanate reaction catalyst added, and water of 0.1 to 0.6 per 100 parts by weight of the polyol component. A method of molding an integral skin foam, comprising the step of injecting into the cavity a polyurethane material added by parts by weight to foam.