JP4201166B2 - Method for producing foamed particle molded body with skin material - Google Patents

Description

【００７１】
【表２】

【００７２】
（１）発泡粒子Ｙの充填量：
成形空間部Ｚの全容積に対して６５ｖｏｌ％（３５ｖｏｌ％は発泡粒子間の空隙である。）
【００７３】
（２）予備加熱工程（該第２成形型の壁面に設けられた透孔からスチームを成形空間部に導入することにより、該成形空間部の発泡粒子を加熱しておこし状物となす工程）
（ｉ）スチーム温度：１５０℃
（ｉｉ）空間Ａ内の圧力：０．３７２ＭＰａ（Ｇ）
（ｉｖ）空間Ｂ内の圧力：０．３７２ＭＰａ（Ｇ）
（ｖ）加熱時間：２秒
【００７４】
（３）スチーム排気工程（成形空間部のスチームを排出した工程）
（ｉ）排気時間：２秒
（ｉｉ）空間Ａ内の圧力：０ＭＰａ（Ｇ）
（ｉｖ）空間Ｂ内の圧力：０ＭＰａ（Ｇ）
【００７５】
（４）本加熱工程の工程Ｐ（該第２成形型の壁面に設けられた透孔から再度スチームを成形空間部に導入することにより、該成形空間部内のおこし状物を加熱する工程）
（ｉ）スチーム温度 ：１５０℃
（ｉｉ）空間Ａ内の圧力：０．３７２ＭＰａ（Ｇ）
（ｉｉｉ）加熱時間：４秒
【００７６】
（５）本加熱工程の工程Ｑ（該第２成形型の壁面に設けられた透孔から再度スチームを成形空間部に導入することにより、該成形空間部内のおこし状物を加熱する工程）
（ｉ）スチーム温度 ：１５０℃
（ｉｉ）空間Ｂ内の圧力：０．３７２ＭＰａ（Ｇ）
（ｉｉｉ）加熱時間：４秒
【００７７】
（６）本加熱工程の工程Ｇ（該第２成形型の壁面に設けられた透孔から再度スチームを成形空間部に導入することにより、該成形空間部内のおこし状物を加熱する工程）
（ｉ）スチーム温度：１５０℃
（ｉｉ）空間Ａ及びＢの圧力：０．３７２ＭＰａ（Ｇ）
（ｉｖ）加熱時間：４秒
【００７８】
前記本加熱後、ドレン排出管のバルブ１９と２５及び水冷水導入管のバルブ１７と２３を開けて７０秒間水冷を行なった後、ドレン排出管のバルブを開けて真空吸引装置（図示せず）により成形空間部Ｚを真空吸引した。第１成形型４の形状に対応する外観形状を有する表面に表皮材が積層接着された発泡粒子成形体が得られた。この成形体においては、その表面部の発泡粒子間には隙間は見られず、その表面部及び内部における発泡粒子相互の融着は良好であり、かつ発泡粒子成形体表面上の表皮材とその発泡粒子（発泡粒子成形体の表面）との融着も良好であり、成形体は全体的にすぐれた機械的強度を有するものであった。
なお、前述した（５）本加熱工程の工程Ｑ及び（６）本加熱工程の工程Ｇでは既におこし状物の間隙が存在しない成形体となっているが、便宜上おこし状物という。
【００７９】
実施例２
本加熱工程の工程Ｇを除いた以外は、実施例１と同様に表皮材付き発泡粒子成形体を製造した。
得られた表皮材付き発泡粒子成形体は、表面部及び内部における発泡粒子相互の融着は良好で、かつ発泡粒子成形体表面上のその表皮材と発泡粒子との融着は良好であった。
【００８０】
実施例３
予備加熱工程の前にスチームのバルブ１５及び２１を開け、ドレン排出管１８及び２４のバルブ１９及び２５を開けて空気排気工程を行なった以外は実施例１と同様に実験を行った。
得られた表皮材付き発泡粒子成形体は、その表面部及び内部における発泡粒子相互の融着が良好で、かつ発泡粒子成形体表面上の表皮材とその発泡粒子との融着も良好であった。
【００８１】
実施例４
本加熱工程の工程Ｇを除いた他は実施例３と同様に行った。
得られた表皮材付き発泡粒子成形体は、その表面部及び内部における発泡粒子相互の融着が良好で、かつ発泡粒子成形体表面上の表皮材とその発泡粒子との融着も良好であった。
【００８２】
なお、実施例１〜４の各々と同じ条件で加熱成形した場合において、おこし状物が形成されていることを次のように確認した。即ち、（２）予備加熱工程直後に成形空間部内のスチームを排出した後、再度スチーム加熱を行なうことなく充分に冷却してから成形体を金型から取り出し、大気圧下、６０℃、相対湿度５０％の条件で４８時間乾燥させ、次いで、大気圧下、２３℃相対湿度５０％の条件で４８時間放置した後、表皮材側を下側に向けて置き、おこし状物の上面に１０℃の水１００ｍｌを１０秒かけて静かに流し、流し終えてから２０秒以内に、おこし状物の下方に位置する表皮材のおこし状物側表面にその水のほとんどが浸透して到達していた。このように、おこし状物は、空隙が発泡粒子間に形成されて発泡粒子同士が融着されている状態であった。
【００８３】
また、実施例１〜４で得られた各々の表皮付き発泡粒子成形体について、おこし状物の空隙が塞がれていることを次のように確認した。即ち、本加熱工程後充分に冷却してから成形体を金型から取り出し、大気圧下、６０℃、相対湿度５０％の条件で４８時間乾燥させ、次いで、大気圧下、２３℃相対湿度５０％の条件で４８時間放置した後、表皮材側を下側に向けて置き、発泡粒子成形体が露出している側の上面に１０℃の水１００ｍｌを１０秒かけて静かに流し、流し終えてから６０秒後であっても、発泡粒子成形体の下方に位置する発泡粒子成形体の表面にその水の一部も浸透して到達しなかった。このように、得られた表皮付き発泡粒子成形体は、空隙が発泡粒子間に形成されておらず発泡粒子同士が融着されている状態であった。
【００８４】
比較例１
（２）の予備加熱工程、（３）のスチーム排気工程、（４）の工程Ｐ及び（５）の工程Ｑを省略し、空気排気工程と本加熱工程の工程Ｇのみを行った以外は、実施例３と同様に行った。
【００８５】
得られた表皮材付き発泡粒子成形体は、該成形体の表面は融着していたが、内部は発泡粒子相互の融着が不十分であった。また、表皮材と発泡粒子成形体表面との融着も不十分で、表皮材を上方に引張ると剥離することが確認された。
【００８６】
比較例２
（３）のスチーム排気工程と（６）工程Ｇを省略した以外は、実施例３と同様に実験を行った。
その結果、比較例１と同様に、得られた表皮材付き発泡粒子成形体は、成形体の表面は融着していたが、内部は発泡粒子相互の融着が不十分であった。また、表皮材と発泡粒子成形体表面との融着も不十分で、表皮材を上方に引張ると剥離することが確認された。
【００８７】
比較例３
実施例３において、（２）の予備加熱工程と（３）のスチーム排気工程を省略した以外は、実施例３と同様に実験を行った。
その結果、得られた表皮材付き発泡粒子成形体は、表皮材と発泡粒子成形体表面との融着が不十分であった。
【００８８】
比較例４
実施例３において、（２）の予備加熱工程と（３）のスチーム排気工程及び（６）本加熱工程の工程Ｇを省略した以外は、実施例３と同様に実験を行った。
その結果、得られた表皮材付き発泡粒子成形体は、表皮材と発泡粒子成形体表面との融着が不十分であった。
【００８９】
実施例１〜４、及び比較例１〜４において得られた表皮材付き発泡粒子成形体について、外観、二次発泡性、及び剥離強度を次の基準で評価した結果を表２に示した。
【００９０】
＜外観の評価＞
表皮付き発泡粒子成形体の発泡粒子相互の間隙による表面外観を、表皮材側において次の基準で評価した。
表面凹凸がない・・・・・・○
表面に凹凸がある・・・・・×
【００９１】
＜二次発泡性の評価＞
表皮付き発泡粒子成形体の発泡粒子成形体が露出している側の表面外観について次の基準で評価した。
発泡粒子相互の間隙がなく表面凹凸がない・・・・・・・・・・・○
発泡粒子相互の間隙が少なく表面の部分的に凹凸がある・・・・・△
発泡粒子相互の間隙が多く表面の全体的に凹凸がある・・・・・・×
【００９２】
＜剥離強度の評価＞
得られた表皮付き発泡粒子成形体より表皮材を含むサンプルサイズ厚さ（ｍｍ）×幅２５（ｍｍ）×長さ２００（ｍｍ）の試験片を切り取り、サンプルの表皮材の一端を付かんでサンプルから試験速度２００ｍｍ／ｍｉｎで９０°剥離強度の測定を行なった。得られた応力より最小と最大を測定しその値の平均値を剥離強度とし、１つの表皮付き発泡粒子成形体よりＮ数を３としてその相加平均値を表２に示す剥離強度とし、該剥離強度の強さに応じて次の基準で評価した。
４．９０Ｎ／２５ｍｍ以上・・・・・・・・・・・○
４．９０Ｎ／２５ｍｍ未満３．９０Ｎ／２５ｍｍ以上・・・・△
３．９０Ｎ／２５ｍｍ未満・・・・・・・・・・・・×
【００９３】
【発明の効果】
本発明の製造方法においては、該第２成形型の壁面に設けられた透孔からスチームを成形空間部に導入することにより、該成形空間部内の発泡粒子を加熱しておこし状物となし、次いで、成形空間部のスチームを排出した後、該第２成形型の壁面に設けられた透孔から再度スチームを成形空間部に導入することにより、該成形空間部内のおこし状物を加熱するので、スチームが成形空間部に均一に行き渡り、発泡粒子と表皮材との融着性、発泡粒子相互の融着性に優れる表皮材付き発泡粒子成形体が得られる。
【００９４】
特に、発泡粒子をおこし状物としてから、再度スチームを成形空間部に導入することにより、該成形空間部内のおこし状物を加熱するので、成形サイクルを短縮することができ、スチームの使用量も少なくすることができ、コストダウンも達成される。
【図面の簡単な説明】
【図１】本発明を実施する場合に用いられる発泡成形装置の一例についての概略図を示す。
【符号の説明】
１ 第１成形型
２ 第２成形型
３ 仕切板
４ 成形用上箱
５ 成形用下箱
１５、２１、１９、２５、１７、２３ 開閉バルブ
１６、２２ 冷却水導入管
１４、２０ スチーム導入管
１８、２４ ドレン排出管
Ｘ 表皮材
Ｙ 発泡粒子
Ｚ 成形空間部[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a method for producing a foamed particle molded body with a skin material, which is obtained by integrating a skin material on the surface of a foamed particle molded body.
[0002]
[Prior art]
A molding method is widely known in which foamed particles are heated and fused using steam after filling the interior space of the mold formed by the first mold and the second mold.
[0003]
The foamed particle molded body obtained by the above molding method is one in which the foamed particles are fused to each other, and the surface has irregularities of the foamed particles and lacks aesthetics. In order to improve this point, it has been proposed to laminate and integrate a skin material on the surface of the foamed particle molded body (see, for example, Patent Document 1, Patent Document 2, Patent Document 3, and Patent Document 4).
[0004]
However, in the case of the conventional method in which the skin material is laminated and integrated, since the fusion between the foamed particles in the obtained molded body is insufficient and the fusion between the skin material and the foamed particles is also insufficient, the molded body Overall, it was inferior in mechanical strength.
[0005]
Therefore, the development of a method for producing a foamed particle molded body with a skin material, in which the fusion strength between the foamed particles and the fusion strength between the skin material and the foamed particles is excellent, and the mechanical strength of the molded body as a whole is also excellent. Was expected.
[0006]
[Patent Document 1]
Japanese Patent Laid-Open No. 58-171921
[Patent Document 2]
JP-A-6-891
[Patent Document 3]
Japanese Patent Laid-Open No. 6-210753
[Patent Document 4]
JP 11-333960 A
[0007]
[Problems to be solved by the invention]
The present invention provides a method for producing a foamed particle molded body with a skin material in which a skin material is laminated and integrated on the surface of the foamed particle molded body, wherein the fusion strength between the foamed particles and the fusion strength between the skin material and the foamed particles are It is an object of the present invention to provide a method for efficiently producing a foamed particle molded body with a skin material which is excellent and has excellent mechanical strength as a whole molded body.
[0008]
[Means for Solving the Problems]
As a result of intensive studies to solve the above problems, the present inventors have completed the present invention. That is, according to the present invention, a method for producing a foamed particle molded body with a skin material described below is provided.
[1] Heating foam particles filled in a molding space formed between a first molding die in which a skin material is arranged along the inner surface and a second molding die provided with a large number of through holes on a wall surface Then, in the method for producing a foamed particle molded body with a skin material having the skin material laminated on the surface by fusing, steam is introduced into the molding space from the through-hole provided in the wall surface of the second molding die The foamed particles in the molding space are heated to form a paste, and after the steam in the molding space is discharged, the steam is again discharged from the through holes provided in the wall surface of the second molding die. A method for producing a foamed particle molded body with a skin material, characterized by heating the braid in the molding space by introducing it into the molding space.
[2] The method for producing a foamed particle molded body with a skin material according to [1], wherein the foamed particles are foamed particles having a polyolefin resin as a base resin.
[0009]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, the method of the present invention will be described in detail with reference to the drawings.
FIG. 1 is a schematic view showing an example of a foam molding apparatus used for carrying out the present invention.
In FIG. 1, 1 is a first mold, 2 is a second mold, 3 is a partition plate, 4 is an upper box for molding, 5 is a lower box for molding, 6 is a vacuum suction hole, 7 is a vacuum suction tube, 8 Denotes an upper box chamber, 11 and 11 (2) denote through holes, 12 denotes a lower box chamber, and 13 denotes a foamed particle supply pipe (hereinafter simply referred to as “supply pipe”). X represents a skin material, Y represents foamed particles, and Z represents a molding space.
[0010]
The 1st shaping | molding die 1 is for forming the external appearance shape of a foaming particle molding, and the skin material X is arrange | positioned at the inner surface.
[0011]
A number of through holes 11, 11 (2) through which steam can permeate are provided on the wall surface of the second mold 2. The diameters of the through holes 11 and 11 (2) are dimensions such that the foamed particles Y do not pass through, and are usually about 0.3 to 1 mm, preferably about 0.5 to 0.7 mm.
[0012]
The partition plate 3 partitions the lower box chamber 12 located on the back surface of the second mold 2 into two separated spaces, that is, a space A and a space B.
[0013]
In the present invention, it is preferable to partition the inside of the chamber located on the back surface of the second mold into at least two separated spaces, and the two separated spaces A and the space from the viewpoint of productivity such that the process is not complicated. It is more preferable to partition into B.
[0014]
In order to fill the expanded particles, when a valve (not shown) of the supply pipe 13 is opened, air is formed between the first mold 1 and the second mold 2 from the supply pipe 13. The foamed particles Y are filled in the molding space Z together with the air flow. Thereafter, the valve of the supply pipe 13 is closed, and the tip of a piston (not shown) in the supply pipe closes the surface of the second mold.
[0015]
The amount of the foamed particles Y filled in the molding space Z is determined so that when the foamed particles Y are molded, a foamed particle molded body having a predetermined density (predetermined expansion ratio) is obtained.
The expanded particles Y can also be filled by a so-called compression filling method in which the expanded particles are crushed and filled in a mold.
[0016]
In the method of the present invention, the foam particles in the molding space Z are heated by introducing steam into the molding space Z from the through holes 11 and 11 (2) provided in the wall surface of the second molding die. No worm-like material (hereinafter also simply referred to as “preheating step”), and after discharging steam in the molding space (hereinafter also simply referred to as “steam discharging step”), the wall surface of the second mold 2 The steam inside the molding space Z is heated by re-introducing steam into the molding space Z from the through holes 11 and 11 (2) provided in the molding space (hereinafter also simply referred to as “main heating step”). To do.
[0017]
According to the production method of the present invention, since the steam is uniformly distributed in the molding space, a foamed particle molded body with a skin material excellent in the fusion property between the foam particles and the skin material and the fusion property between the foam particles can be obtained. It is done. In addition, the molding cycle can be shortened and the amount of steam used can be reduced, so that the cost can be reduced.
[0018]
As in the method of the present invention, if the foamed particles are not heated in the preheating step to form a flake, a foamed particle molded body with a skin having good adhesion between the skin material and the foamed particles can be obtained in the subsequent step. It may take time and the molding cycle may be long. On the other hand, if it is heated until the foamed particles are fused and the gap disappears after passing through the braided material, when the steam is introduced again into the molding space in the next step, the steam passage is obstructed. Even if it has been done, there is a possibility that the foamed particle molded body cannot be practically used because of poor fusion between the foamed particles and between the foamed particles and the skin material.
[0019]
In the method of the present invention, the braid is a case where after the steam in the molding space is discharged in the subsequent step of the preheating step, the foamed particles are taken out of the mold after sufficiently cooling without performing the steam heating again. It means a state in which continuous voids exist between the expanded particles forming the braid. More specifically, after the steam in the molding space is discharged in the subsequent process of the preheating process, the foamed particles are taken out from the mold after sufficiently cooling without performing the steam heating again, and the atmospheric pressure is 60 ° C. , Dried for 48 hours at 50% relative humidity, and then left for 48 hours at 23 ° C. and 50% relative humidity under atmospheric pressure. 100 ml of water at 10 ° C. was gently poured over 10 seconds, and within 20 seconds after the completion of the flow, at least part of the water penetrated into the surface of the surface of the skin material located below the surface of the surface A state in which voids that reach each other are formed between the expanded particles and the expanded particles are fused to each other is referred to as a paste.
[0020]
In the preheating process described above, steam is introduced into the molding space Z from all the through holes 11 and 11 (2) provided in the wall surface of the second molding die 2 in order to make the expanded particles Y into a sag. Then, the pressure in the molding space may be increased so that the foamed particles Y filled in the molding space Z are heated and fused to form a foamed product. At this time, it is preferable to heat so that the time during which the pressure is increased to a temperature at which the expanded particles Y are fused to each other is 4 seconds or less. If it exceeds 4 seconds, it is difficult to make a braid and the molding cycle may be long. From this viewpoint, it is preferably 3 seconds or less, and the lower limit thereof is approximately 1 second.
[0021]
An example of a specific operation in the preheating step will be described.
First, the valve 15 of the steam introduction pipe 14 communicating with the space A and the space B shown in FIG. 1 and the valve 21 of the steam introduction pipe 20 communicating with the space B are opened, and the other valves, that is, the valve 17, Steam 19 is introduced into the space A and the space B through the valve 15 of the steam introduction pipe 14 and the valve 21 of the steam introduction pipe 20 with the valves 19, 23 and 25 closed.
[0022]
When the steam is introduced into the space A and the space B in this way, the steam passes through the numerous through holes 11 and 11 (2) provided in the wall surface of the second mold 2 facing the space A and the space B. Since it enters the molding space Z facing the space A and the space B, the surface of the foamed particles Y and the skin material X are preheated.
[0023]
When steam is introduced into the molding space in the preheating step, it is possible to introduce steam from some through holes or from all through holes, but it is possible to fuse with foamed particles in a short time. From the viewpoint that the surface of the skin material can be preheated, it is preferable to introduce steam from all through holes into the molding space.
[0024]
In the method of the present invention, a steam exhaust process is performed after the preheating process. In the exhaust process, the steam in the molding space is exhausted, so that the steam efficiently reaches the molding space in the next main heating process. As a result, in the next main heating process, the fusion between the foamed particles and the fusion between the foamed particles and the skin material can be done in a short time, and the molding cycle is shortened, so the amount of steam used is reduced and the cost is reduced. It becomes possible.
[0025]
A specific steam exhaust process is performed, for example, by opening only the valve 19 of the drain discharge pipe 18 and the valve 25 of the drain discharge pipe 24 which were closed in the preheating process. In the steam exhaust process, all or part of the steam in the forming space may be discharged.
[0026]
In the method of the present invention, the main heating step is performed after the steam exhausting step. In the main heating step, steam is introduced again into the molding space Z from the through holes 11 and 11 (2) provided on the wall surface of the second molding die 2 so that the braid in the molding space Z is removed. Heat. As a result, the fusion strength between the heated foam particles can be increased, and the fusion strength between the foam particles and the skin material can be increased.
[0027]
After the main heating step, the molded body is sufficiently cooled and taken out from the mold. The obtained foamed molded article with skin is that the foamed particles are fused together, and there are no continuous voids present between the foamed particles when formed into a braid in the preheating step. preferable. Specifically, after sufficiently cooling after the main heating step, the molded body is taken out from the mold, dried under atmospheric pressure at 60 ° C. and a relative humidity of 50% for 48 hours, and then at atmospheric pressure at 23 ° C. After leaving for 48 hours at a relative humidity of 50%, place the skin material side down and gently pour 100 ml of water at 10 ° C. over 10 seconds on the upper surface where the foamed particle molded body is exposed. Even after 60 seconds from the end of the flow, a gap is formed between the foam particles so that a part of the water penetrates and reaches the surface of the foam particle molded body located below the foam particle molded body. It is preferable that the expanded particles are fused together.
[0028]
As the main heating process, for example, a heating process for introducing steam into at least two times by changing the introduction position of the steam to the molding space part, or a heating process for introducing steam from all through holes into the molding space part Is mentioned. Among them, by adopting a heating process that introduces steam at least twice by changing the introduction position of the steam to the molding space, even when the shape of the foamed particle molded body is complicated or thick, By changing the through holes 11 and 11 (2) for introducing steam, the expanded particles Y existing in the molding space Z can be efficiently heat-sealed.
[0029]
As a preferable aspect of the main heating step for changing the steam introduction position with respect to the molding space, a step including a first main heating step and a main heating step different from the first main heating step may be mentioned. In this first heating step (hereinafter, simply referred to as “step P”), the chamber located on the back surface of the second mold is partitioned into a plurality of separated spaces, and the first heating step formed in the chamber is performed. Steam is introduced into one space, the steam is introduced into the molding space through the first through hole provided in the wall surface of the second molding die facing the first space, and is introduced into the molding space. The steam is discharged into the second space from the second through hole provided in the wall surface of the second mold facing the second space different from the first space formed in the chamber. Is done by. The main heating step (hereinafter simply referred to as “step Q”) different from the first main heating step is opposite to the first main heating step, and the wall surface of the second mold facing the second space. Steam is introduced into the second space from the second through-hole provided in the first through-hole provided in the wall of the first mold facing the first space. This is done by discharging into one space. Thus, it is preferable to perform the main heating step including the step P and the step Q, since the fusion between the expanded particles and the fusion between the expanded particles and the skin material are improved.
[0030]
An example for carrying out the process P and the process Q of the main heating process will be described with reference to FIG.
First, the steam is introduced into the space B through the valve 21 of the steam introduction pipe 20, and the molding space is then passed through the numerous through holes 11 (2) provided in the wall of the second molding die 2 facing the space B. After introducing steam into the portion Z and allowing the steam to flow in the left direction in the drawing through the forming space portion Z, the steam passes through a large number of through-holes 11 formed in the wall surface of the second forming die 2 facing the space A. Steam is discharged into space A. At that time, the valves 25, 23, 19, 17 and 15 are closed.
[0031]
Next, the steam is introduced into the space A through the valve 15 of the steam introduction pipe 14, and from there into the molding space Z through a large number of through holes 11 formed in the wall surface of the second mold 2 facing the space A. After introducing steam and flowing the steam through the molding space Z in the right direction in the drawing, the steam passes through a large number of through-holes 11 (2) provided in the wall surface of the second molding die 2 facing the space B. In this case, the valves 25, 23, 19, 17, and 21 are closed.
[0032]
Thus, by performing the process P and the process Q of the heating process, the foamed particles 9 in the molding space Z can be uniformly heated to a state suitable for thermoforming. In addition, when performing the process P and the process Q of a heating process in this way, if foam is introduce | transduced into one space B or A and the other space A or B is pressure-reduced, an expanded particle can be heated uniformly. preferable.
[0033]
In the main heating step of the method of the present invention, after performing the heating step consisting of the step P and the step Q in which the steam introduction position with respect to the molding space is changed, the steam introduction pipe 14 is formed in all the spaces formed in the chamber. , 20 valves 15 and 21 are opened to introduce steam, and the steam is introduced into the molding space through the through holes provided in the wall surface of the second molding die facing the entire space (hereinafter referred to as “the heating process”). It is preferred to simply perform "Step G"). When heating is performed in this manner, the foamed particles in the molding space are more preferably heated and fused, and a foamed particle molded body in which the foamed particles are fused to each other without any gap can be obtained.
[0034]
A specific example for carrying out the step G will be described with reference to FIG.
The drain discharge pipe valve 19, the cooling water introduction pipe valve 17, the drain discharge pipe valve 25, and the cooling water introduction pipe 22 valve 23 are kept closed, and the steam introduction pipe 14 valve 15 and the steam introduction pipe 20 are closed. The steam 21 is kept open and steam is introduced into the spaces A and B through the steam introduction pipes 14 and 20, respectively. When operated in this way, steam is introduced into the forming space Z from the through holes 11 and the through holes 11 (2) provided in the walls A and B, that is, the wall surfaces of the second forming die 2 facing all the spaces. be able to.
[0035]
The temperature of the steam used in the heating step is a temperature at which the foamed particles are fused, and specifically, (Tv + 0 ° C.) to (Tv + 50 ° C.) with respect to the Vicat softening temperature Tv of the thermoplastic resin constituting the foamed particles. Are preferable, and (Tv + 0 ° C.) to (Tv + 40 ° C.) are more preferable. The pressure of the steam in the spaces A and B is preferably 0.098 to 0.441 MPa (G), more preferably 0.196 to 0.392 MPa (G). The heating time is usually preferably 3 to 20 seconds, and more preferably 5 to 15 seconds.
[0036]
After the heating step is completed, the foamed particle molded body is cooled, then the first molding die 1 and the second molding die 2 are opened, the excess skin material is removed, and the foamed particle molded body with the skin material is collected, which is necessary. It is preferable to carry out curing and drying at 40 to 80 ° C. for 3 to 24 hours.
[0037]
As described above, the foamed particle molded body with a skin material obtained by the method of the present invention is a production method including a preheating step, a steam exhausting step, and a main heating step. The fusion strength between the particles and the skin material is excellent, and the mechanical strength of the entire foamed particle molded body is greatly improved as compared with the conventional foamed particle molded body with a skin material.
[0038]
Moreover, when the process G is implemented in this heating process, the fusion strength between the foam particles and the fusion strength between the foam particles and the skin material can be further improved.
[0039]
Before the preheating step, a step of exhausting air (hereinafter simply referred to as “air exhausting step”) may be included as necessary. Specifically, an air exhaust process is illustrated in which the valves 15 and 21 of the steam introduction pipes 14 and 20 and the valves 19 and 25 of the drain discharge pipes 18 and 24 are opened to exhaust the air between the foam particles in the molding space Z. The
[0040]
The shape of the foamed particle molded body with a skin material of the present invention can be set to an arbitrary shape by changing the shape of the mold.
[0041]
Although the method of the present invention has been described with reference to FIG. 1, the method of the present invention is not limited to this, and various modifications can be made. For example, the number of the partition plates 3 disposed in the chamber located on the back surface of the second mold is not limited to one, and may be a space divided into a plurality of, for example, two by two partition plates. In this case, a space C is formed between the space A and the space B in the chamber. In the case of such three spaces, after introducing steam into the intermediate space C and circulating it in the molding space portion Z, the through hole A of the second molding die facing the space A of the second molding die 2 From the through hole B of the second mold facing the space B, and into the space B. Of course, also in this case, a steam introduction pipe having an opening / closing valve is connected to the space C.
[0042]
Furthermore, the method for introducing steam into the molding space Z is to introduce steam a plurality of times through the through-holes formed in the wall surface of the second molding die, and through different through-holes for each introduction. However, it is not always necessary to partition the chamber into a plurality of spaces using a partition plate. For example, the introduction of steam into the molding space Z is also performed by a method in which the tip of the steam supply pipe is formed into a flat plate shape or a curved plate shape, and the tip is directly in contact with the wall surface of the second mold. can do.
[0043]
The method of the present invention obtains a high-quality foamed particle molded article with a skin material without introducing steam directly into the surface of the skin material as a product by introducing steam from the through-hole of the wall surface of the second mold. Can do. Therefore, for example, when the surface of the skin material is a non-woven fabric, hair fall does not occur, and in the case of a resin sheet, the surface does not become uneven.
[0044]
In the above description, the heating process for introducing steam from the through hole of the second mold has been described. However, if necessary, steam is introduced into the upper box chamber 8, and the steam is inserted into the through hole of the first mold. May be introduced into the molding space.
[0045]
Hereinafter, the expanded particles used in the method of the present invention will be described.
The foamed particle is a thermoplastic resin foamed particle containing a gas (organic gas such as hydrocarbon gas or halogenated hydrocarbon gas, or inorganic gas such as carbon dioxide gas, nitrogen or air) in its interior. It will soften. As such a thing, conventionally well-known various things can be used. Examples of the thermoplastic resin constituting the expanded particles include polycarbonate resin, polyethylene terephthalate resin, vinyl chloride resin, polystyrene resin, acrylic resin, nylon resin, and polyolefin resin.
[0046]
Among the thermoplastic resins constituting the foamed particles, polyolefin resins are preferable because they are excellent in buffering properties and compressive strain recovery properties. Examples of the polyolefin resin include low density polyethylene, medium density polyethylene, high density polyethylene, linear low density polyethylene, linear ultra-low density polyethylene, ethylene-propylene block copolymer, and ethylene-propylene random copolymer. , Ethylene-butene block copolymer, ethylene-butene random copolymer, ethylene-vinyl acetate copolymer, ethylene-methyl methacrylate copolymer, ethylene-methacrylic acid copolymer ionomers crosslinked with metal ions Resin, propylene homopolymer, propylene-ethylene random copolymer, propylene-butene random copolymer, propylene-ethylene block copolymer, propylene-butene block copolymer, propylene-ethylene-butene terpolymer , Propire - acrylic acid copolymers, propylene - maleic anhydride copolymer, other, polybutene include polypentene, and mixtures thereof. In addition to these, a copolymer of an olefin monomer such as ethylene, propylene, butene and pentene and a monomer such as styrene which can be copolymerized with these olefin monomers can also be used. Among these, a polypropylene resin excellent in compressive strength and heat resistance is preferable.
[0047]
In the method of the present invention, the above-mentioned polyolefin resin may be used by crosslinking with peroxide or radiation, or it may be used as it is without cross-linking. preferable.
[0048]
The expanded particles used in the method of the present invention can be produced by, for example, the following conventionally known methods.
First, a thermoplastic resin is extruded into a strand using an extruder, cooled through water, and then cut into resin particles. In this case, the thermoplastic resin may contain various conventional additives such as fillers, stabilizers, reinforcing agents, pigments, and lubricants. Next, the resin particles are impregnated with an inorganic gas-based foaming agent and / or a volatile organic foaming agent while being stirred with water in a sealed pressure vessel, for example, and heated to a predetermined foaming temperature under pressure. Thereafter, it can be obtained by a method such as discharging to a low pressure region.
[0049]
The apparent density of the expanded particles used in the method of the present invention is usually 0.015 to 0.450 g / cm. ³ , Preferably 0.030-0.300 g / cm ³ It is. Apparent density 0.015g / cm ³ If it is less, the strength of the obtained foamed molded product may be weakened. On the other hand, the apparent density is 0.450 g / cm. ³ If it exceeds 1, the resulting foamed molded product may lack the light weight characteristic of the foam.
Moreover, the average particle diameter is 1-7 mm, Preferably it is 1-5 mm.
[0050]
The apparent density is measured as follows.
1000 foamed particle groups were sampled, dried for 24 hours under conditions of a temperature of 60 ° C. and a relative humidity of 15%, and then allowed to stand for 24 hours under conditions of a temperature of 23 ° C. and a relative humidity of 50%. Next, the weight of this sample: W (g) was measured, and then the sample was submerged in ethanol at 23 ° C. in a graduated cylinder, and the true volume of the sample: L (cm ³ ) And measured by the following formula (1).
[0051]
[Expression 1]
Apparent density of expanded particles (g / cm ³ ) = W ÷ L (1)
[0052]
The amount of heat of the high-temperature side endothermic peak of the expanded particles Y used in the method of the present invention is 5 to 60 J / g in order to increase the mechanical strength of the obtained expanded molded body when forming the expanded particles Y. It is desirable from the viewpoint that gaps are generated between the foamed particles of the molded body, and the gaps are not transferred as traces on the surface of the skin material, and that mechanical properties of the foamed molded body with skin, particularly compressive strength can be increased. . When the base resin of the expanded particles Y is a propylene homopolymer, the amount of heat at the high temperature peak is preferably 15 J / g or more, and 20 J / g or more from the viewpoint of increasing the compression strength of the obtained foamed product with skin. Is more preferable. On the other hand, 60 J / g or less is preferable and 55 J / g or less is more preferable from the viewpoint of reducing the reduction effect of the molding temperature. When the base resin of the expanded particles Y is a propylene-ethylene random copolymer, the amount of heat at the high temperature peak is preferably 5 J / g or more from the viewpoint of increasing the compressive strength of the obtained foamed product with skin. 10 J / g or more is more preferable. On the other hand, the upper limit is preferably 30 J / g or less from the viewpoint of preventing gaps between the foamed particles of the obtained foamed molded article with skin, and preventing the gaps from being transferred as traces on the surface of the skin material. / G or less is more preferable.
[0053]
The high temperature side endothermic peak of the expanded particles is the same as that expressed as “high temperature peak heat quantity” in JP-A No. 2002-53692, and JP-A Nos. 61-4738 and 8-259724. The “secondary crystal” described in the above item appears on the DSC curve due to the presence of the expanded polypropylene resin particles. Therefore, when secondary crystallization is not performed in the production process of the expanded particles, the high-temperature side endothermic peak does not appear in the obtained expanded particles. Further, even if the foamed particles have a high temperature side endothermic peak, for example, if the foamed particles are melted by raising the temperature to a temperature equal to or higher than the melting end temperature of the high temperature side endothermic peak, the secondary crystal disappears. Even in the measurement sample, the high-temperature endothermic peak does not appear. The method for adjusting the amount of heat of fusion of the high-temperature endothermic peak of the expanded particles is as described in the above-mentioned known literature. In the production of a foamed molded product, the expanded particles in which the high temperature side endothermic peak appears tend to have a low defective product generation rate and a high mechanical strength of the resulting foamed molded product.
[0054]
Next, the skin material used in the method of the present invention will be described.
In order to obtain the shape intended for the skin material used in the present invention, a so-called sheet molding method in which a single-layer sheet or a multilayer sheet is softened by heating and molded with a mold, or a so-called sheet molding method in which powder resin is applied to a mold is heat-molded. A slush molding method, an injection molding method, or the like is used. Among these, a sheet forming method excellent in productivity and economy is preferable.
[0055]
Examples of the sheet forming method include, for example, vacuum forming and pressure forming using a male and / or female mold, and free drawing forming, plug and ridge forming, ridge forming, and matched use as these applications. -Mold molding, straight molding, drape molding, reverse draw molding, air slip molding, plug assist molding, plug assist reverse draw molding, and a molding method combining these.
[0056]
As the sheet used in the sheet forming method, conventionally known various single layer or multilayer sheets are used. Examples of the single-layer sheet include fiber fabrics such as woven fabrics, knitted fabrics, and nonwoven fabrics, and resins such as foamed resins and non-foamed resins. Examples of the base resin for the single-layer sheet include the thermoplastic resins described for the foamed particles. Among them, a sheet made of a thermoplastic resin that can be fused with the foamed particles is particularly preferable. Moreover, it is preferable that the surface (inner side surface) of the sheet to be fused with the foamed particles is roughened so as to be easily fused.
[0057]
When a multilayer sheet is used as the skin material, the number of layers constituting the multilayer sheet is 2 to 6, preferably 2 to 3. Specific examples of the multilayer sheet include, for example, a sheet in which the outer layer is made of an olefin-based thermoplastic elastomer, the inner layer (the layer in which the foamed particles are fused) is a crosslinked polypropylene resin foam, and the outer surface is polychlorinated. A multilayer sheet made of vinyl, the inner layer is made of a crosslinked polypropylene resin foam, the outer layer is made of fiber cloth (woven fabric, knitted fabric, nonwoven fabric, etc.), and the inner layer is made of resin (non-foamed resin, foamed resin, in particular, From the point of shape retention of the skin material formed by the multilayered sheet consisting of a cross-linked polypropylene resin foam from the point of excellent cushioning properties, the outer surface is made of natural, synthetic leather or olefinic thermoplastic elastomer, and the inner layer is molded A multilayer sheet made of a non-foamed resin, whose intermediate layer is a cushion layer (foamed resin, fibrous body, etc.), and one surface of the single-layer sheet described above is in contact with the foam particles Multilayer sheet or the like attached to the adhesive layer in advance that can be cited. The inner layer is preferably composed of a resin that can be fused to the expanded particles.
[0058]
In addition, since the external appearance will become beautiful when the embossed pattern etc. are transcribe | transferred on the surface of the sheet-like skin material used by the method of this invention, ie, a single layer sheet, or a multilayer sheet, it is preferable. The texture pattern may be transferred in advance or may be transferred when a sheet-like skin material is formed.
[0059]
Despite the use of a single layer sheet or multilayer sheet that can be fused to the expanded particles, the single layer sheet or multilayer sheet and the expanded particles are fused even if steam is introduced into the upper box chamber 8. The method of the present invention is particularly effective when it is difficult to do.
[0060]
The skin material used in the present invention is used for covering the surface of the foamed particle molded body to improve the aesthetics of the surface of the molded body, so that the fusion property with the surface of the foamed particle molded body is improved. In addition, it is necessary to form the foamed particle molded body into a shape corresponding to the surface shape (the inner surface shape of the first mold that determines the surface shape).
[0061]
The thickness of the single layer sheet used for sheet molding is 0.5 to 5 mm, preferably 0.5 to 3 mm. The multilayer sheet has a thickness of 1 to 7 mm, preferably 1 to 5 mm.
[0062]
In the method of the present invention, when producing a foamed particle molded body with a skin material, a method in which the foamed particles are heat-molded using a sheet material that has been molded in advance, and at the same time the skin material and the foamed particles are fused, or one mold And a method of fusing the skin material and the foamed particles at the same time as filling and foaming the foamed particles. Among these, from the viewpoint of productivity, a method of heat-molding the sheet molding and the foamed particle molded body with the latter one mold is preferable.
[0063]
The foamed particle molded body with a skin material obtained by the method of the present invention is suitably used for automobile members such as bumpers, door trims and instrument panels, box materials, electronic equipment, pallets and the like.
[0064]
【Example】
Next, the present invention will be described in more detail with reference to examples.
[0065]
Example 1
A foamed particle molded body with a skin material was produced using the apparatus shown in FIG.
Apparent density is 0.180 g / cm ³ (Expanding ratio: 5 times), polypropylene resin expanded particles containing air with an internal pressure of 0 MPa (G) (propylene-ethylene random copolymer, 2.4% by weight of ethylene component, melting point 146 ° C., high temperature peak heat 9.3 J / g, average particle size: 4 mm). The Vicat softening temperature of the polypropylene resin constituting the expanded particles is 132 ° C.
[0066]
Moreover, the surface side layer consists of an olefinic thermoplastic elastomer and a thickness of 0.7 mm, and the intermediate layer is a cross-linked polypropylene resin foam sheet (trade name “Toraypef AP67” manufactured by Toray Industries, Inc., expansion ratio 20 times, thickness 2.5 mm), and a three-layer sheet (total thickness: 3.6 mm) in which the inner surface side layer (the layer to be fused with the foamed particles) is made of an olefin-based thermoplastic elastomer was used as the skin material.
[0067]
The sheet-like skin material was supported by a rectangular frame, and the sheet-like skin material was heated by upper and lower heaters. The heating time was 90 seconds, a thermo label was attached to the skin material, and the surface temperature of the skin material was measured. As a result, the surface temperature of the side disposed along the inner surface of the first mold was 170 ° C., and the surface temperature of the skin material fused with the foamed particles was 125 ° C. Subsequently, the upper mold box 4 and the lower mold box 5 are clamped using the apparatus shown in FIG. 1, and the first mold 1 and the first mold 2 are heated to about 100 ° C. The box 4 and the molding lower box 5 are opened so that the distance between the molding upper box 4 and the molding lower box 5 is 160 mm, and the supported sheet-like skin material is used as the first molding die 1 and the second molding die. 2 in the middle. Next, the sheet is heated for 3.5 seconds with 0.20 MPa (G) steam from the second mold 2 to soften the sheet, and the upper box 4 for molding and the lower box 5 for molding are clamped, and at the same time, the vacuum suction tube 8 The upper box chamber 8 located on the back surface of the first mold 1 is sucked through the substrate 7 for 7 seconds to form the skin material X, and the skin material is disposed on the inner surface of the first mold 1.
[0068]
Next, the molding upper box 4 and the molding lower box 5 were opened, the interval between the molding upper box 4 and the molding lower box 5 was set to 3.5 mm, and the following amount of expanded particles Y was filled. Next, a foamed particle molded body with a skin material was produced under the following main operating conditions.
[0069]
In addition, the opening and closing of the valve | bulb of the steam introduction pipe | tube for every process was shown in Table 1 about Example 1 (For Example 2-4 and Comparative Examples 1-4, the opening / closing of the valve was similarly shown in Table 1). In the table, reference numerals 15 and 19 are the same as those in FIG. 1 and denote a steam introduction pipe valve 15 and a drain discharge pipe valve 19 in the space A, respectively. In the table, reference numerals 21 and 25 are the same as those in FIG. 1, and indicate the steam introduction pipe valve 21 and the drain discharge pipe valve 25 in the space B, x indicates that the valve is closed, and ● indicates that the valve is closed. Means open. In addition, the heating conditions of the skin material and the composite conditions of the skin material and the foamed particle molded body are shown in Table 2 (the heating conditions of the skin material, the skin material, and the like in Examples 2 to 4 and Comparative Examples 1 to 4) The composite conditions with the foamed particle molded body are shown in Table 1.)
[0070]
[Table 1]

[0071]
[Table 2]

[0072]
(1) Filling amount of expanded particles Y:
65 vol% with respect to the total volume of the molding space Z (35 vol% is a space between the expanded particles).
[0073]
(2) Preheating step (step of heating the foamed particles in the molding space portion to form a paste by introducing steam into the molding space portion from the through hole provided in the wall surface of the second molding die)
(I) Steam temperature: 150 ° C
(Ii) Pressure in space A: 0.372 MPa (G)
(Iv) Pressure in space B: 0.372 MPa (G)
(V) Heating time: 2 seconds
[0074]
(3) Steam exhaust process (process in which steam in the molding space is discharged)
(I) Exhaust time: 2 seconds
(Ii) Pressure in space A: 0 MPa (G)
(Iv) Pressure in space B: 0 MPa (G)
[0075]
(4) Step P of the main heating step (step of heating the braid in the molding space by re-introducing steam into the molding space from the through-hole provided in the wall surface of the second molding die)
(I) Steam temperature: 150 ° C
(Ii) Pressure in space A: 0.372 MPa (G)
(Iii) Heating time: 4 seconds
[0076]
(5) Step Q of the main heating step (step of heating the braid in the molding space by re-introducing steam into the molding space from the through hole provided in the wall surface of the second molding die)
(I) Steam temperature: 150 ° C
(Ii) Pressure in space B: 0.372 MPa (G)
(Iii) Heating time: 4 seconds
[0077]
(6) Step G of the main heating step (step of heating the braid in the molding space by reintroducing steam into the molding space from the through hole provided in the wall surface of the second mold)
(I) Steam temperature: 150 ° C
(Ii) Pressure in spaces A and B: 0.372 MPa (G)
(Iv) Heating time: 4 seconds
[0078]
After the main heating, the drain discharge pipe valves 19 and 25 and the water-cooled water introduction pipe valves 17 and 23 are opened for water cooling for 70 seconds, and then the drain discharge pipe valve is opened and a vacuum suction device (not shown). Thus, the molding space Z was vacuumed. A foamed particle molded body in which the skin material was laminated and adhered to the surface having the appearance corresponding to the shape of the first mold 4 was obtained. In this molded body, there is no gap between the foam particles on the surface portion, the fusion between the foam particles on the surface portion and inside is good, and the skin material on the surface of the foam particle molded body and its The fusion with the expanded particles (the surface of the expanded particle molded body) was also good, and the molded body had excellent mechanical strength as a whole.
In addition, in the above-mentioned (5) Step Q of the main heating step and (6) Step G of the main heating step, the molded product has no gaps between the braids, but for convenience, it is referred to as a braid.
[0079]
Example 2
A foamed particle molded body with a skin material was produced in the same manner as in Example 1 except that the step G of the main heating step was omitted.
The obtained foamed particle molded body with a skin material had good fusion between the foamed particles on the surface and inside, and the fusion between the skin material and the foamed particles on the surface of the foamed particle molded body was good. .
[0080]
Example 3
The experiment was performed in the same manner as in Example 1 except that the steam valves 15 and 21 were opened before the preheating step, and the valves 19 and 25 of the drain discharge pipes 18 and 24 were opened to perform the air exhausting step.
The obtained foamed particle molded body with a skin material has good fusion between the foamed particles on the surface and inside thereof, and also has good fusion between the skin material on the surface of the foamed particle molded body and the foamed particles. It was.
[0081]
Example 4
The same procedure as in Example 3 was performed except for the step G of the main heating step.
The obtained foamed particle molded body with a skin material has good fusion between the foamed particles on the surface and inside thereof, and also has good fusion between the skin material on the surface of the foamed particle molded body and the foamed particles. It was.
[0082]
In addition, when it heat-molded on the same conditions as each of Examples 1-4, it confirmed that the braid was formed as follows. That is, (2) after discharging steam in the molding space immediately after the preheating step, after sufficiently cooling without performing steam heating again, the molded product is taken out from the mold, and at 60 ° C. and relative humidity under atmospheric pressure. After drying for 48 hours under the condition of 50% and then leaving to stand for 48 hours under the condition of atmospheric pressure and 23 ° C. and relative humidity of 50%, the skin material side is placed facing down and 10 ° C. on the top surface of the cake. 100 ml of water was gently poured over 10 seconds, and within 20 seconds after the completion of the flow, most of the water had penetrated and reached the surface of the surface of the surface of the skin material located below the surface of the surface of the surface. . Thus, the braid was in a state in which voids were formed between the expanded particles and the expanded particles were fused together.
[0083]
Moreover, about each foamed particle molded object with a skin obtained in Examples 1-4, it confirmed as follows that the space | gap of a braided object was block | closed. That is, after sufficiently cooling after the main heating step, the molded body is taken out from the mold and dried for 48 hours at 60 ° C. and 50% relative humidity under atmospheric pressure, and then at 23 ° C. and 50% relative humidity. For 48 hours, place the skin material side down and gently pour 100 ml of water at 10 ° C over 10 seconds onto the upper surface where the foamed particle molded body is exposed. Even after 60 seconds, part of the water penetrated and did not reach the surface of the foamed particle molded body located below the foamed particle molded body. Thus, the obtained foamed particle molded body with skin was in a state in which no voids were formed between the expanded particles and the expanded particles were fused together.
[0084]
Comparative Example 1
(2) The preliminary heating process, (3) the steam exhaust process, (4) the process P and (5) the process Q are omitted, and only the air exhaust process and the main heating process G are performed. The same operation as in Example 3 was performed.
[0085]
In the obtained foamed particle molded body with a skin material, the surface of the molded body was fused, but the inside was insufficiently fused between the foamed particles. Moreover, the fusion between the skin material and the surface of the foamed particle molded body was insufficient, and it was confirmed that the skin material was peeled off when pulled upward.
[0086]
Comparative Example 2
The experiment was performed in the same manner as in Example 3 except that the steam exhausting step (3) and the step (6) were omitted.
As a result, as in Comparative Example 1, the obtained foamed particle-molded article with a skin material was fused on the surface of the molded article, but the inside was insufficiently fused between the foamed particles. In addition, the fusion between the skin material and the surface of the foamed particle molded body was insufficient, and it was confirmed that the skin material peels when pulled upward.
[0087]
Comparative Example 3
In Example 3, an experiment was performed in the same manner as in Example 3 except that the preheating step (2) and the steam exhausting step (3) were omitted.
As a result, the obtained foamed particle molded body with a skin material was insufficient in fusion between the skin material and the surface of the foamed particle molded body.
[0088]
Comparative Example 4
In Example 3, an experiment was performed in the same manner as in Example 3 except that the preheating step (2), the steam exhausting step (3), and the step G (6) of the main heating step were omitted.
As a result, the obtained foamed particle molded body with a skin material was insufficient in fusion between the skin material and the surface of the foamed particle molded body.
[0089]
Table 2 shows the results of evaluating the appearance, secondary foamability, and peel strength of the foamed particle molded bodies with skin material obtained in Examples 1 to 4 and Comparative Examples 1 to 4 according to the following criteria.
[0090]
<Appearance evaluation>
The surface appearance of the foamed particle molded body with a skin due to the gap between the foamed particles was evaluated on the skin material side according to the following criteria.
No surface irregularities ...
Uneven on the surface ... ×
[0091]
<Evaluation of secondary foamability>
The surface appearance on the side where the foamed particle molded body of the foamed molded body with skin was exposed was evaluated according to the following criteria.
There are no gaps between the foam particles and there are no surface irregularities.
There are few gaps between the expanded particles, and the surface is partially uneven.
There are many gaps between the expanded particles, and the entire surface is uneven.
[0092]
<Evaluation of peel strength>
Cut out a test piece of sample size thickness (mm) x width 25 (mm) x length 200 (mm) including the skin material from the obtained foamed molded article with skin, and attach one end of the sample skin material to the sample. The 90 ° peel strength was measured at a test speed of 200 mm / min. From the obtained stress, the minimum and maximum values were measured, the average value of the values was taken as the peel strength, the N number was 3 from one foamed molded article with a skin, and the arithmetic average value was taken as the peel strength shown in Table 2, The evaluation was made according to the following criteria depending on the peel strength.
4.90N / 25mm or more
Less than 4.90N / 25mm 3.90N / 25mm or more ...
3. Less than 90N / 25mm ・ ・ ・ ・ ・ ・ ・ ・ ・ ・ ・ ×
[0093]
【The invention's effect】
In the production method of the present invention, by introducing steam into the molding space from the through-hole provided in the wall surface of the second mold, the foamed particles in the molding space are heated to form a paste, Next, after the steam in the molding space is discharged, the steam in the molding space is heated by re-introducing the steam into the molding space from the through hole provided in the wall surface of the second mold. As a result, it is possible to obtain a foamed particle-molded article with a skin material, in which steam uniformly spreads over the molding space, and is excellent in the meltability between the foamed particles and the skin material and between the foamed particles.
[0094]
In particular, the foam particles are made into a cake, and the steam in the molding space is heated by introducing steam again into the molding space, so that the molding cycle can be shortened and the amount of steam used is also reduced. The cost can be reduced and the cost can be reduced.
[Brief description of the drawings]
FIG. 1 shows a schematic diagram of an example of a foam molding apparatus used in the case of carrying out the present invention.
[Explanation of symbols]
1 First mold
2 Second mold
3 Partition plate
4 Upper box for molding
5 Lower box for molding
15, 21, 19, 25, 17, 23 Open / close valve
16, 22 Cooling water introduction pipe
14, 20 Steam introduction pipe
18, 24 Drain discharge pipe
X skin material
Y foam particles
Z molding space

Claims (2)

The foam particles filled in the molding space formed between the first mold having the skin material disposed along the inner surface and the second mold having a large number of through holes provided on the wall surface are heated and melted. In the method for producing a foamed particle molded body with a skin material, on which the skin material is laminated, by introducing steam into the molding space through a through-hole provided in the wall surface of the second molding die Then, the foamed particles in the molding space are heated to form a paste, and after the steam in the molding space is discharged, the steam is again formed from the through holes provided in the wall surface of the second molding die. A method for producing a foamed particle molded body with a skin material, characterized by heating the braided material in the molding space portion by introducing into the molding space. The method for producing a foamed particle molded body with a skin material according to claim 1, wherein the foamed particles are foamed particles having a polyolefin resin as a base resin.

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