This application claims priority to Japanese Patent Application No. 2011-264912 filed on Dec. 2, 2011, the disclosure of which including the specification, the drawings, and the claims is hereby incorporated by reference in its entirety.
The present disclosure relates to sound insulation materials which are to be used in places requiring sound insulation, e.g., buildings, vehicles, and aircraft, and enclose granular elastic materials of rubber or thermoplastic elastomers, and methods for preparing such sound insulation materials.
As a sound insulation material of this type, Japanese Patent Publication No. H08-185188 proposes, for example, a sound insulation material in which a granular elastic material of, for example, pulverized rubber, previously formed granular rubber, or a rubber-like elastic resin is covered with a cover layer of a sheet made of nonwoven fabric or a resin, a sound insulation material in which a latticed partition plate or a plurality of partition boxes filled with a granular elastic material is interposed between cover layers, and a sound insulation material in which the cover layer is provided integrally with a projection for separation. Japanese Patent Publication No. 2003-150169 proposes, for example, a sound insulation material prepared by filling a bag constituted by, for example, woven fabric, nonwoven fabric, or a resin film with pulverized foam particles and sealing the bag and a sound insulation material prepared by connecting, with pins or by sewing, both sides of a bag enclosing foam particles. Japanese Patent Publication No. S57-183953 proposes a packaging bag housing powder in which a center portion of the bag is sealed with heat in order to prevent collapse when bags with a uniform thickness are stacked.
A sound insulation material prepared by filling a bag with a granular elastic material has a high sound deadening property. However, in application of such a sound insulation material in a place where vibration occurs, e.g., vehicles or aircraft, vibration causes uneven distribution of a granular elastic material 2 filling a bag 1 as illustrated in
The above-described structures in which the inside of the bag is partitioned by the latticed partition plate or partition boxes, bags are connected together with pins or by sewing, or the center portion of the bag is sealed with heat, can inhibit movement of the granular elastic material to prevent uneven distribution of the granular elastic material and, thereby, uniformize the thickness. However, preparation of a sound insulation material by the process of filling a latticed partition plate or partition boxes with a granular elastic material, providing a cover, and then welding the rim of the cover with heat or the process of partially welding the rim of a cover with heat to form a bag, filing the bag with a granular elastic material through an unwelded portion, and then inserting pins into, or sewing, the bag, causes an increase in the number of parts, leading to a complicated structure and also an increase in the number of processes. As a result, the cost increases. In addition, in the case of connecting bags with pins, water might enter from portions at which the pins are inserted. In this aspect, in the packaging bag whose center portion is sealed with heat, heat sealing on the center portion is performed simultaneously with heat sealing on the rim of the bag. Thus, the structure and processes are simplified, thereby reducing the cost. However, in filling a bag with a granular elastic material, a center portion of the bag sealed with heat tends to be an obstacle to the filling.
It is therefore an object of the present disclosure to provide a sound insulation material which can reduce uneven distribution of an enclosed granular elastic material and has a small variation in thickness, a simple structure, can be prepared by simple processes, and can be easily filled with the granular elastic material, and a method for preparing such a sound insulation material.
A sound insulation material in an aspect of the present disclosure includes a bag which is closed at a rim thereof and is made of nonwoven fabric or a resin sheet; and a granular elastic material enclosed in the bag, and a joint portion projecting inward from the rim of the bag is located on at least a portion of the rim of the bag.
In this sound insulation material, even with vibration, the joint portion projecting inward from the rim can inhibit movement of the granular elastic material. Accordingly, uneven distribution of the granular elastic material can be prevented or reduced. Consequently, a variation in the sound deadening property can be reduced. In addition, the joint portion can reduce a variation in the thickness of the sound insulation material. Thus, problems such as a trouble in parts around the sound insulation material caused by bulging and limited design in layout are less likely to occur. Further, in forming the joint portion, the unnecessity of parts and processes dedicated to prevention of uneven distribution can reduce the cost. Moreover, since the joint portion projects from the rim and no joints are provided at the center of the bag in injecting the granular elastic material into a center portion of the bag, advantages in which the joint is less likely to interfere the injection, for example, can be achieved.
In a preferred aspect of the present disclosure, the joint portion has a tapered shape whose width gradually decreases toward a center of the bag. With this structure, in injecting the granular elastic material, even when the granular elastic material comes into contact with the joint, the granular elastic material can be relatively smoothly injected. As a result, the granular elastic material can reach every corner of the bag.
In a preferred aspect of the present disclosure, the granular elastic material enclosed in the bag is at least partially made of foam rubber or a foam resin. Thus, the sound insulation property can be further enhanced.
In a preferred aspect of the present disclosure, the joint portion projects inward to a distance at which the joint does not interfere injection of the granular elastic material when a nozzle for injecting the granular elastic material is inserted into a center portion of the bag to fill the bag with the granular elastic material. With this structure, in injecting the granular elastic material with the nozzle, the insertion of the nozzle into the center portion of the bag can be smoothly performed.
A method for preparing the sound insulation material described above in an aspect of the present disclosure includes either folding nonwoven fabric or a resin sheet into two sheets or stacking two sheets of nonwoven fabric or a resin, and bonding rims of the two sheets together except for portions of the rims, thereby forming a bag; filling the bag with a granular elastic material through portions of the rims which are not bonded; and bonding the portions of the rims which are not bonded after filling the bag with the granular elastic material. In the bonding of the rims, a portion to be bonded on the rim and at least a projecting portion to be bonded projecting inward from the rim in one of the sheets are bonded at the same time to a portion to be bonded on the rim and a projecting portion to be bonded projecting inward from the rim in the other sheet.
A sound insulation material according to an embodiment of the present disclosure will be described hereinafter with reference to the drawings.
The joints 13a, 13b, 13c, and 13d are constituted by triangles 13c and 13d and square shapes 13a and 13b which are different from one another in degrees of projection, size, and shape. The shapes of the joint portions are not limited to those illustrated in
The joint portions 13a, 13b, 13c, and 13d provided on opposed sides of the bag 11 are also designed so as not to interrupt insertion of a nozzle, which will be described later, even with the maximum amount of projection toward the center of the bag. This projection amount is, for example, preferably 3 mm or more, more preferably 5 mm or more, much more preferably 10 mm or more, and preferably less than or equal to a half of the width of the bag 11.
The joint portions 13a, 13b, 13c, and 13d of the bag 11 have various shapes and sizes. Alternatively, all the joint portion may have the same shape and the same size.
The above-described sound insulation material of this embodiment is the bag 11 formed by stacking two sheets of nonwoven fabric or a resin and bonding the entire rims together. Alternatively, a single sheet of nonwoven fabric or a resin may be used such that the sheet is folded into two sheets and the other three sides of one of the sheets are bonded to the three associated sides of the other.
The joint 13 and the joint portions 13a, 13b, 13c, and 13d, or 19 are formed by, for example, heat welding, adhesion, or sewing as described above, or a combination of these processes. Among these processes, heat welding (heat sealing) is preferable. This is because the heat welding can be easily carried out, and enables the joints 13, 13a, 13b, 13c, and 13d, or 19 at the same time with the same process, thereby reducing the number of processes, and also reducing the preparation cost.
In forming the bag 11, the joint 13 is not formed in part of a rim of the bag, i.e., at the center of the side provided with the projection 11b in the illustrated example, in order to inject the granular elastic material. An opening 15 communicating the inside of the bag is formed by bonding both sides of the projection 11b. In injecting the granular elastic material 12 through the opening 15, one or more nozzles 16 with adjusted dimensions as illustrated in the drawing are used. Each of the nozzles 16 is inserted through the opening 15 to a distance of a half or more of the length of the bag 11 along the insertion direction. The joint portions 13a, 13b, 13c, and 13d project inward from the rim, and the amounts of projection are determined so as not to interrupt the insertion of the nozzles. Thus, the nozzles 16 can be smoothly inserted. After the insertion of the nozzles 16, the granular elastic material 12 is blown out and injected. To allow the granular elastic material 12 to be blown out and injected, the bag 11 has air permeability. To provide the bag 11 with air permeability, the bag 11 is preferably made of nonwoven fabric.
The granular elastic material 12 to be injected is, for example, an elastic material obtained by pulverizing used rubber or a used resin product of a rubber-like elastic material used for a weatherstrip or other types of sealers of vehicles or cushioning materials, or an elastic material dedicated to use for sound insulation materials. The granular elastic material 12 may be in a foam state or a solid state. Among these materials, a material obtained by pulverizing used rubber or a used resin product is preferably employed, and the resin product of rubber or a rubber-like elastic material is more preferably in a foam state. Recycling a used rubber product or a used resin product can save resources, and reduce the cost. The use of foam rubber or a foam resin can enhance the sound absorption (sound deadening) property. The granular elastic material 12 is not specifically limited in size and shape. The size of the granular elastic material 12 is in the range from 0.1 mm to 10 mm in most cases.
Examples of the rubber or the rubber-like elastic material described above include rubber such as EPDM rubber and natural rubber, thermoplastic elastomers (olefin-based TPO and styrene-based TPS). In the case of foam rubber, rubber having a specific gravity of 0.03-1.0 is used.
The granular elastic material 12 does not need to be entirely made of the same material, and may be made of a mixture of materials having different properties (e.g., compositions and specific gravities).
After the granular elastic material 12 has been injected into the bag 11 through the nozzles 16, an opening in a side in which the projection 11b is provided is closed by bonding. Simultaneously with closing this opening by bonding, the joint portions 13a, 13b, 13c, and 13d, or 19 may be formed.
After bonding the sides, the projection 11b is removed. This removal of the projection 11b may be performed by cutting with a cutter. Preferably, the projection 11b is removed by melting simultaneously with bonding by heat welding. Then, the bonding and the melting can be performed at the same time in a single process. The removal of the projection 11b may be performed before bonding the side so that the bonding is performed after the removal.
The sound insulation materials 17, 18, and 21 of the foregoing embodiments have rectangular outer shapes, but may have outer shapes conforming to the shapes of the joint portions. The sound insulation material 23 illustrated in
In the manner described above, the sound insulation material 17 enclosing the granular elastic material is prepared. In this sound insulation material, the joint portions 13a, 13b, 13c, and 13d can reduce movement of the granular elastic material 12, resulting that uneven distribution of the granular elastic material 12 can be reduced and a substantially uniform thickness can be maintained.
Number | Date | Country | Kind |
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2011-264912 | Dec 2011 | JP | national |