JP3104567U - Soft composite structure with breathability - Google Patents

Abstract

The present invention provides a flexible composite structure having air permeability. Three layers of a foam layer, a resin layer, and a membrane layer in which rubber materials having the same compatible interface are bonded at adjacent contact surfaces. The foamed layer 11 is formed through a foaming step, so that the foamed layer 11 has a plurality of ventilation holes 110, the resin layer 12 is provided with a plurality of openings 120, and the surface of the resin layer 12 is Of the same kind of rubber material. With this structure, a soft composite structure having extremely excellent vibration absorption, uniform resilience, recovery, air permeability, and heat radiation can be obtained at the same time.
[Selection diagram] Fig. 1

Description

  The present invention relates to a flexible composite structure having air permeability, and particularly to a material having uniform resilience, recovery, vibration absorption, and air permeability. The present invention relates to a flexible composite structure having air permeability that can be used in the air conditioner.

  At present, generally speaking, a vibration absorbing material is generally a foam material (for example, polystyrene) or a cushion body having closed cells, and the foam material and the closed cell cushion body each have a limited application range. The closed-cell cushion body is applied only for vibration damping of heavy objects and is not used for vibration damping of general objects only.

  In addition, due to the limitations of physical factors, the above-mentioned vibration-absorbing material cannot have high vibration absorption, resilience and recovery at the same time because the vibration absorption and resilience are inversely proportional. The physical properties of materials and elastic materials are contradictory, and vibration-absorbing materials used in precision equipment such as electronic equipment, communication equipment, industrial equipment, packaging equipment, etc. have relatively excellent vibration isolation protection when transporting those equipment. If only the effect is given, if the vibration absorbing material is used for daily necessities such as pillows, cushions, bed mattresses, shoe soles, etc., it lacks resilience, recovery and air permeability.

  As can be understood from the above description, if there is a composite material having relatively excellent resilience, recovery, vibration absorption, and air permeability at the same time, it can be used simultaneously as a vibration absorption material and household goods, and its economic effect and convenience Needless to say. However, although many manufacturers have focused on their research development, none has yet been widely used due to its relatively good construction. However, the inventor of the present invention continued research and improvement, and finally devised the present invention.

  The main object of the present invention is to provide a flexible composite structure having air permeability, in which rubber materials of the same compatible interface of a foam layer, a resin layer, and a film layer are bonded at adjacent contact surfaces. It is a fixed structure with multiple openings in the resin layer.It also has excellent vibration absorption, uniform resilience, recovery, ventilation and heat dissipation at the same time. It is a new technology that provides an effective solution because it has a material structure that has both resilience, recovery, vibration absorption, and air permeability.

In order to solve the above problems,
The invention of claim 1 is a soft composite structure having air permeability, and mainly has a three-layer structure in which rubber materials having compatible interfaces having the same properties are bonded and fixed at adjacent contact surfaces. ,
The three layers are constituted by a foam layer, a resin layer, and a film layer,
The foamed layer has a plurality of air holes by being generated through a foaming step, has a further uniform resilience, has recoverability, and has a feature of being excellent in supportability.
The foam layer has a resin layer of the same kind of rubber material fixed thereto, and the resin layer is non-foamed at room temperature, has flexibility, and has a plurality of openings in the resin layer. It has a very excellent ventilation heat dissipation effect as a whole, and greatly enhances the shock absorbing capacity of the resin layer,
The surface of the resin layer is covered with a single layer of a rubber material of the same type of rubber, the film layer is solidified into a thin film as soft as human skin, and the film layer is formed of a resin layer. It is a soft composite structure having air permeability, characterized in that the adhesiveness can be reduced.

  The invention according to claim 2 is the air-permeable flexible composite structure according to claim 1, wherein the plurality of openings of the resin layer communicate with the air holes of the foam layer.

  The invention according to claim 3 is the breathable soft composite structure according to claim 1, wherein the rubber material is formed by mixing raw materials obtained by combining elastomer polyurethane (polyurethane resin). is there.

  The invention according to claim 4 is the breathable soft composite structure according to claim 1, wherein the foam layer, the resin layer, and the membrane layer are installed in a pillow shape.

  The invention according to claim 5 is the breathable soft composite structure according to claim 1, wherein the foam layer, the resin layer, and the membrane layer are installed in a cushion shape.

  The invention according to claim 6 is the breathable soft composite structure according to claim 1, wherein the foam layer, the resin layer, and the membrane layer are installed in a bed mattress shape.

1 Excellent vibration absorption, recovery, and air permeability.
By actual measurement, the Tg VALUE value surely decreases, and the resilience value of the present invention increases. The larger the value, the more excellent the resilience. Therefore, the present invention has high vibration absorption and resilience at the same time. In addition to the above-mentioned structure, the present invention has an excellent point that the air hole of the foam layer and the opening structure of the resin layer are added, and the air permeability is good. And achieve the required quality.

2 It can be applied to rebound and anti-vibration materials.
The present invention has relatively excellent uniform resilience, resilience, and high vibration absorption effect, so it can be used simultaneously for resilience materials (shoe insole, etc.) or vibration-proof materials with different weights. It has an excellent point that it can be used.

3 Can be widely used for anti-vibration materials.
Since the present invention has plasticity, it has an extremely excellent vibration absorption property, and therefore, a structure in which the resin layer peristes at the opening is added, and the present invention is widely used for various shapes, weights, and vibration isolation of large and small objects. It can be applied and replaces known foams and closed cell cushions.

4 The structure is not easily destroyed.
The foam layer, resin layer, and film layer of the present invention have an overall structure in which rubber materials having compatible interfaces of the same properties are bonded and fixed at adjacent contact surfaces, so that they are not easily separated. Therefore, the present invention has an extremely excellent structure.

5. High quality, able to meet economic demands.
The present invention solves the problem of the work of laminating layers manually by forming a film layer, a resin layer, and a foam layer by automated molding using a production line method, and using an automated production structure that does not use this adhesive. In addition, it is possible to avoid the occurrence of a situation in which the original design requirement of the product in the known structure is impaired, which is excellent in that the production efficiency is further improved and the whole is beautiful.

FIG. 1 is a cross-sectional view of the present invention. As can be seen from the drawing, the present invention mainly includes a foam layer 11, a resin layer 12, and a film layer 13. 12, the membrane layer 13 has a cushion structure in which rubber materials having a compatible interface of the same property are bonded and fixed at adjacent contact surfaces,
The foamed layer 11 has a plurality of air holes 110 by being formed through a foaming process, thereby greatly increasing the ventilation effect, keeping the inside cool, and providing a dry and comfortable touch. It has the characteristics that it can provide comfort, has uniform rebound and recovery, and has excellent support.
The foamed layer 11 has a resin layer 12 of the same kind of rubber material fixed thereto. The resin layer 12 is non-foamed at room temperature, has flexibility, and has a plurality of openings in the resin layer 12. A portion 120 is provided, and a vent 110 of the foam layer 11 is added to the entire structure, thereby having an extremely excellent ventilation and heat radiation effect on the whole, and greatly improving the deformation preventing ability of the resin layer 12. And the amount of raw material used for the resin layer 12 is reduced, and the total weight is reduced. Since the resin layer 12 has flexibility and non-foaming properties, the cost is relatively high. The structure can achieve the economic principle of reducing the amount of raw material used for the resin layer 12.

  In addition, the surface of the resin layer 12 is covered with one layer of a rubber layer 13 of the same type of rubber material, and the film layer 13 is solidified into a flexible thin film like human skin. The layer 13 can reduce the adhesiveness of the surface of the resin layer 12.

  FIGS. 2, 3, 4, 5, and 6 show an actual manufacturing situation of the present invention. As shown in FIGS. 2 and 3, first, a mold 20 is prepared, and a finished product is placed in the mold 20. Is provided, and a resin layer forming unit 22 is provided at the bottom of the cavity 21. The resin layer forming unit 22 has a wall surface for forming the opening 120, and thereafter, As shown in FIG. 4, a predetermined amount of rubber material is sprayed on the surface of the resin layer forming unit 22 in advance, and is solidified into a thin film layer 13 having a smooth feel of human skin. The rubber material is a raw material obtained by combining an elastomer polyurethane (polyurethane resin) and is composed of at least two or more kinds of compounds, one of which is a cross-linking agent. In the present invention, a PU main agent (for example, Polyol) is used. A combination of two kinds of raw materials of a cross-linking agent (for example, MDI) is adopted, and the mixture is set at a predetermined ratio (the description of the material is not a limiting factor of the present invention).

  After the film layer 13 is solidified, a certain amount of the same kind of rubber material is poured into the resin layer forming unit 22 again as shown in FIG. 5, but the proportion of the crosslinking agent must be smaller than that of the film layer 13. The layer 12 does not foam at room temperature, has flexibility after solidification, has the property of easily adjusting to the stress received, and has the property of peristalsis and deformation. Particularly important here is the resin layer 13. Has good vibration absorption and peristaltic properties, so its surface is sticky, even after it has solidified, and its feel is not comfortable, so it cannot be used directly by the user However, since the film layer 13 and the resin layer 12 form a bonded state in which rubber materials of compatible interfaces having the same properties are bonded and fixed at adjacent contact surfaces, the film layer 13 is formed on the outer surface of the resin layer. Can be isolated, so that users are in direct contact Live without.

As shown in FIG. 6, after the resin layer 12 is solidified, the same type of foamed rubber material is directly poured into the cavity 21, and the foamed layer 11 is formed and solidified on another surface of the resin layer 12.
Since the foamed layer 11 is manufactured by a foaming process, the foamed layer 11 has a plurality of air holes 110, and the foamed layer 11 and the resin layer 12 are bonded by a rubber material having a compatible interface having the same property at adjacent contact surfaces. Since it is in a bonded state, the structure of the foam layer 11, the resin layer 12, and the film layer 13 of the present invention is a structure that is bonded together without using an adhesive and is integrally formed, and has a uniform resilience. Used as a material with resilience, vibration absorption and air permeability.

 In the present invention, the resin layer 12 and the foam layer 11 are formed first, and after taking out from the mold, a rubber material is sprayed on the resin layer 12 to form the film layer 13.

  FIG. 7 shows an embodiment in which the present invention is specifically applied to a pillow. In this embodiment, it is necessary to provide a cavity of a horseshoe mold having a relatively high center portion on both sides in the mold. Only in this order, according to the order, the corresponding shape of the film layer 13, the resin layer 12, and the foam layer 11 are formed. The resin layer 12 provides resilience, recovery, and shock absorption, and the fixability of the foam layer 11 is excellent. The opening 120 has a ventilation effect, so that the whole structure provides good support to the cervical vertebra, and also provides a sweat absorbing heat radiation effect to the head, so that the sleeping phase is stable and comfortable The best pillow structure to sleep on. In the present invention, in the molding process, the film layer 13, the resin layer 12, and the foam layer 11 can be molded by the production line type automatic molding, and the work of bonding the layers by known human power can be performed more conveniently and at a high speed. In this way, the revolutionary advanced creation and economic effect of the present invention can be surely exhibited, production efficiency can be more effectively increased, and by adopting automatic processing, In addition to speed and convenience, it is an automated production structure that does not use adhesives, so it greatly enhances the texture and appearance of the whole product, and inevitably makes known production more complicated than manual labor It also avoids mistakes caused by busy, inadvertent, emotionally unstable, or inexperienced operators.

  As can be seen from another embodiment of FIG. 7, the present invention can be applied to a structure such as a cushion, a bed mattress, a shoe insole, and the like, and the purpose is achieved only by changing the shape according to the application. Can be.

  There are pillows, cushions, bed mattresses, shoe mats, and the like that apply the structure of the present invention to vibration absorption and daily necessities, and have the following excellent points during use.

1 Excellent vibration absorption, recovery, and air permeability.
By actual measurement, the Tg VALUE value surely decreases, and the resilience value of the present invention increases. The larger the value, the more excellent the resilience. Therefore, the present invention has high vibration absorption and resilience at the same time. In addition to the above-mentioned structure, the present invention has an excellent point that the air hole of the foam layer and the opening structure of the resin layer are added, and the air permeability is good. And achieve the required quality.

2 It can be applied to rebound and anti-vibration materials.
The present invention has relatively excellent uniform resilience, resilience, and high vibration absorption effect, so it can be used simultaneously for resilience materials (shoe insole, etc.) or vibration-proof materials with different weights. It has an excellent point that it can be used.

3 Can be widely used for anti-vibration materials.
Since the device of the present invention has flexibility, it has an extremely excellent vibration absorbing property, and therefore a structure in which the resin layer peristes at the opening is added, and the present invention is applicable to various shapes, weights, vibration damping of large and small objects. It can be widely applied to, and replaces known foam materials and closed cell cushion bodies.

4 The structure is not easily destroyed.
The foam layer, resin layer, and film layer of the present invention have an overall structure in which rubber materials having compatible interfaces of the same properties are bonded and fixed at adjacent contact surfaces, so that they are not easily separated. The present invention has extremely excellent structural durability.

5. High quality, able to meet economic demands.
The present invention solves the problem of the work of laminating layers manually by forming a film layer, a resin layer, and a foam layer by automated molding using a production line method, and using an automated production structure that does not use this adhesive. In addition, it is possible to avoid the occurrence of a situation in which the original design requirement of the product in the known structure is impaired, which is excellent in that the production efficiency is further improved and the whole is beautiful.

  As described above, the feature of the present invention lies in the structure of a foam layer, a resin layer having openings, and a glossy and smooth film layer, which can be molded at one time, and the processing is fast and accurate. In addition, it is excellent in shape followability and hard to be defective, effectively enhances the added value of the product, has air permeability and heat dissipation effect, and more importantly, the structure of the present invention has particularly excellent peristaltic properties It has very excellent uniform rebound, recovery, and vibration absorption properties, is a very outstanding and excellent design, and has not been used for publication or public use yet. The application conforms to the application requirements for a utility model, and the application is made in accordance with the law.

It is sectional drawing of this invention. FIG. 3 is a top view of the mold according to the present invention. FIG. 4 is a sectional view of the mold according to the present invention. FIG. 4 is a view showing the formation of a film layer in the present invention. FIG. 4 is a diagram illustrating the molding of the resin layer according to the present invention. FIG. 3 is a view showing the formation of a foam layer according to the present invention. It is a figure which shows a mode that this invention was implemented in the production of a pillow.

Explanation of reference numerals

DESCRIPTION OF SYMBOLS 11 Foam layer 110 Vent hole 12 Resin layer 120 Opening 13 Film layer 20 Die 21 Cavity 22 Resin layer molding unit

Claims (6)

It is a soft composite structure with air permeability, consisting of a three-layer structure where homogeneous rubber materials of the same quality are joined at adjacent joint surfaces,
The three layers are constituted by a foam layer, a resin layer, and a film layer,
The foamed layer is generated through a foaming step, and has a plurality of air holes, thereby having resilience, recoverability, and imparting supportability,
The resin layer is fixed by compatibility with a foam layer of the same type of rubber material, the resin layer is non-foamed at room temperature, has flexibility, and has a plurality of openings in the resin layer. By being provided, it gives ventilation heat dissipation throughout and at the same time gives the resin layer the ability to prevent deformation,
The surface of the resin layer is covered with a layer of the same type of rubber material, thereby providing flexibility of human skin and shielding the surface from stickiness of the resin layer. A soft composite structure with a characteristic air permeability.   The flexible composite structure having air permeability according to claim 1, wherein the plurality of openings of the resin layer communicate with the air holes of the foam layer.   The air-permeable flexible composite structure according to claim 1, wherein the rubber material is formed by mixing raw materials obtained by employing a polyurethane resin.   The flexible composite structure having air permeability according to claim 1, wherein the foam layer, the resin layer, and the membrane layer are formed in a pillow shape.   The air-permeable flexible composite structure according to claim 1, wherein the foam layer, the resin layer, and the membrane layer are formed in a cushion shape.   The air-permeable flexible composite structure according to claim 1, wherein the foam layer, the resin layer, and the membrane layer are formed in a bed mattress shape.

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