KR20210099702A - Vertical type sound-absorbing materials using PET FELT and method for manufacturing the same - Google Patents

Abstract

The present invention relates to a vertical arrangement-type sound absorption and blocking material and a manufacturing method thereof and, more specifically, to: a vertical arrangement-type sound absorption and blocking material which has a multi-layer structure in which a horizontally arranged sound absorption and blocking material layer and a vertically arranged sound absorption and blocking material layer are laminated and has a surface-treated nonwoven fabric attached to the outer surface thereof to suppress dust generation and increase the uniformity of the surface; and a manufacturing method thereof. Accordingly, the vertical arrangement-type sound absorption and blocking material is finished by attaching a thin surface-treated nonwoven fabric to the outer surface, thereby preventing generation of dust on the surface and increasing uniformity of the surface. In addition, the vertical arrangement-type sound absorption and blocking material is manufactured to have a multilayered structure in which a horizontally arranged sound absorption and blocking material layer, which is a high-density layer, and a vertically arranged sound absorption and blocking material layer, which is a low-density layer, are mixed and laminated so that a difference in surface densities is generated between the layers, thereby reducing weight and increasing sound absorption performance due to the difference in surface densities.

Description

Vertical type sound-absorbing materials using PET FELT and method for manufacturing the same

The present invention relates to a sound absorbing and insulating material having a vertically arranged structure using PET felt and a method for manufacturing the same. The present invention relates to a sound absorbing and insulating material to which a surface-treated nonwoven fabric is attached, which improves the uniformity of the surface while suppressing the generation of dust, and a method for manufacturing the same.

In general, as a representative noise introduced into the interior of a vehicle, there is an engine transmission noise generated from an engine and transmitted through a vehicle body or air.

In order to suppress the engine transmission noise, a typical vehicle uses an engine cover or a hood insulator, but there is a limit and insufficient points in removing the noise to a desired level only through these.

Accordingly, sound absorbing and insulating materials are applied to various locations in automobiles. For example, in order to block noise generated in the engine room, the sound absorbing and insulating material is installed on the dash panel that separates the engine room and the vehicle room, and also reduces the noise transmitted from the car floor. A sound absorbing and insulating material for blocking is provided on a floor panel or the like.

In the dash panel, the dash outer attached to the exterior of the vehicle and the dash inner attached to the interior of the vehicle play a role in removing most of the noise.

In addition, the sound absorbing and insulating material installed on the floor panel is installed while being spread on the bottom surface of the floor carpet as shown in FIG. Noise and noise generated when the tire and the road surface are in contact are largely divided into noise introduced through the vehicle body.

In general, sound absorption means that the generated sound energy is converted into thermal energy and disappears as it is transmitted through the internal path of the material.

The sound absorption performance is mainly related to the internal shape of the material, and the sound insulation performance is closely related to the density and structure of the material.

That is, in order to satisfy the sound absorption performance, there must be many fine open cell particles such as urethane foam, and in the case of felt, it is already known that a fiber having a low fineness must be used.

In addition, by varying the areal density of the sound absorbing and insulating material using the principle that energy loss is increased when the work of the plane and the plane is different in the sound absorbing and insulating material, better performance can be exhibited compared to the same areal density.

In order to improve the sound insulation performance, it is a common technology to use a heavy layer material, which is a separate sound insulation material.

As described above, in automobiles, sound absorbing and insulating materials are applied to various locations including the dash panel, floor panel, door panel, roof panel, and various other interior materials, which are the parts where noise is introduced the most.

Polyurethane foam or fibrous felt is used as a material of the sound absorbing and insulating material. In particular, recently, polyethylene terephtalate (PET) felt has been widely used to improve sound absorption and heat insulation performance.

Polyurethane foam has been widely used as a sound-absorbing material that has been conventionally used to suppress noise, but in the case of urethane foam, it has excellent sound-absorbing properties, but a sound-insulating material called a separate heavy layer is inserted and used because the sound insulation is deteriorated. .

However, in this case, the sound insulation is improved to some extent, but the total assembly weight increases due to the insertion of the high-density heavy layer, so the fuel efficiency of automobiles decreases and the manufacturing cost increases due to the need to prepare a separate mold for urethane foam. there is.

In addition, since the heavy layer cannot be recycled after use, there are problems such as environmental problems and separate disposal costs.

Accordingly, recently, many products have been used that use polyester from which the heavy layer is removed to lower the weight and improve sound absorption and sound insulation performance.

On the other hand, a general sound absorbing and insulating material is manufactured by mixing a low-melting-point fiber binder (LMF) and a high-melting-point fiber (SF) in a predetermined ratio, stacking layers in a horizontal arrangement, and then performing thermal sealing or needle punching.

In more detail, after mixing a polyester-based low-melting-point fiber binder (LMF) and a high-melting-point fiber (SF) at a predetermined fineness ratio and weight ratio, such as a polyester-based, polyolefin-based, or the like, needle punching or a general cotton process is performed so that the apparent density is different. At this time, thin nonwoven layers are stacked in a horizontal arrangement and then heat-sealed or needle punched so that the layers are bonded to each other.

However, in this conventional sound absorbing and insulating material, there is a problem in that dust is generated due to PET (short fiber) having a horizontal arrangement structure as shown in FIG.

Although the generation of dust on cotton is very low compared to the widely used resin felt, dust is occasionally generated due to the conditions in the production process or the use of recycled materials.

In addition, due to the PET (short fiber) of the horizontal arrangement structure, the sound absorbing and insulating material on the side has problems such as peeling easily (causes dust) or the adhesive surface is falling off.

In particular, the sound absorbing and insulating material is attached to the structure by applying an adhesive. However, when the sound absorbing and insulating material is attached to a curved portion of the structure, there are problems such as peeling of the shoulder surface from the curved surface or the adhesive surface falling off. In the panel, a separate sound absorbing and insulating material is used on the locally curved surface.

In addition, even when the sound absorbing and insulating material is attached to a narrow and long part of the structure, due to the horizontal arrangement structure, peeling occurs easily even if only a little force is applied carelessly when attaching, and the adhesive surface easily falls off.

In addition, PET felt used as a sound absorbing and insulating material at the bottom of the carpet is horizontally arranged and has a high weight (2160 g), and the use of such a heavy felt causes various problems such as fuel economy.

Accordingly, there is a need for a sound absorbing and insulating material having a new structure with a reduced weight and improved sound absorbing performance at the same time.

Accordingly, the present invention was invented in consideration of the above, and provides a sound absorbing and insulating material capable of preventing dust from being generated on the surface by attaching a thin surface-treated nonwoven fabric to the surface and finishing it, and a method for manufacturing the same.

In addition, the present invention provides a sound absorbing and insulating material having a relatively low-density vertically arranged sound absorbing and insulating material layer and a high-density horizontally arranged sound absorbing and insulating material layer having improved sound absorbing and insulating performance while reducing weight, and a method for manufacturing the same.

In one embodiment, the sound absorbing and insulating material having a vertical arrangement includes a multi-layered sound absorbing and insulating material layer in which a plurality of fiber sound absorbing and insulating material layers are stacked, and a surface-treated nonwoven fabric attached to one or both surfaces of the sound absorbing and insulating material main layer, wherein the The sound absorbing and insulating material main layer includes a vertically arranged sound absorbing and insulating material layer having a structure in which a web is formed in multiple layers in a vertical arrangement.

In one embodiment, the sound absorbing and insulating material main layer consists of an intermediate insertion layer as the vertically arranged sound absorbing and insulating material layer, and the upper and lower layers of the intermediate insertion layer as horizontally arranged sound absorbing and insulating material layers having a structure in which a horizontal web is laminated. layer structure.

Here, the vertically arranged sound absorbing and insulating material layer includes a wave shape stacked in a vertical arrangement by being closely folded at the same time as the web is erected.

In addition, in the vertically arranged sound absorbing and insulating material layer, a nonwoven fabric capable of weaving wave vertices is adhered to the upper or lower surfaces or both upper and lower surfaces of a vertically arranged structure in which a web is folded in a wave shape.

In addition, each sound absorbing and insulating material layer of the sound absorbing and insulating material main layer is composed of a high-melting PET fiber of 2 to 15 denier and a low-melting PET fiber of 2 to 6 denier.

In addition, the total thickness of the sound absorbing and insulating material main layer is 5 to 100 mm.

Also, the vertically arranged sound absorbing and insulating material layer of the sound absorbing and insulating material main layer has a thickness of 1 to 50 mm.

In addition, the sound absorbing and insulating material main layer has a total areal density of 800 to 9000 g/m 2 .

In addition, the vertically arranged sound absorbing and insulating material layer of the sound absorbing and insulating material main layer has an areal density of 100 to 3000 g/m 2 .

In addition, the main layer of the sound absorbing and insulating material has a flow resistance value of 500 to 30000 Ns/m 3 .

In addition, the surface-treated nonwoven fabric has a minimum thickness of 0.5 mm and an areal density of 15 g/m 2 .

In addition, the surface-treated nonwoven fabric is composed of a high-melting PET fiber of 2 to 15 denier and a low-melting PET fiber of 2 to 6 denier.

On the other hand, the present invention, (a) opening and carding a low-melting-point fiber binder and a high-melting-point fiber, manufacturing a raw cotton of a horizontally arranged structure in which a horizontal web is laminated; (b) sequentially laminating the raw surface of the horizontal arrangement structure, the sound absorbing and insulating material of the vertical arrangement structure in which multiple layers are formed in a vertical arrangement of the web, and the surface-treated nonwoven fabric attached to the outer surface of one or both sides; (c) Thereafter, subsequent processes including preheating, melting, compression, and cutting are sequentially performed to form a multi-layered sound absorbing and insulating material main layer in which a horizontally arranged sound absorbing and insulating material layer and a vertically arranged sound absorbing and insulating material layer are stacked, and the sound absorbing and insulating material main layer There is provided a method for manufacturing a sound absorbing and insulating material having a vertically arranged structure, comprising the step of completing a final sound absorbing and insulating material product composed of a surface-treated nonwoven fabric attached to one or both surfaces of the sound absorbing and insulating material.

As described above, according to the sound absorbing and insulating material having a vertical arrangement structure and its manufacturing method according to the present invention, a thin surface-treated nonwoven fabric is attached to the outer surface and finished, thereby preventing the single-fiber PET from peeling off the surface. , it is possible to prevent the generation of dust in advance, and has the effect of increasing the uniformity of the surface.

In addition, the high-density horizontally arranged PET sound absorbing and insulating material layer and the low-density vertically arranged PET sound absorbing and insulating material layer have a multi-layered structure in which they are mixed and laminated, thereby showing a difference in areal density between layers. The sound absorption performance has the effect of further improving.

In addition, the vertically arranged PET sound absorbing and insulating material newly used in the present invention has excellent elastic recovery and repulsion (having excellent resilience), does not peel off in any case, and by using the vertically arranged PET sound absorbing and insulating material, It has an additional effect compared to the conventional sound absorbing and insulating material composed only of horizontally arranged materials, such as ensuring matching properties and moldability.

1 is a cross-sectional view showing an embodiment of a sound absorbing and insulating material according to the present invention.
2 is a cross-sectional view schematically illustrating the structure of a vertically arranged sound absorbing and insulating material layer included in the sound absorbing and insulating material of the present invention.
3 is a perspective view illustrating a sawtooth cylindrical device for making a sound absorbing and insulating material having a vertically arranged structure in the present invention.
4 is a cross-sectional view schematically showing a state in which a wave-shaped web is made by the sawtooth-shaped cylindrical device shown in FIG. 3 .
5 is a process chart for manufacturing a sound absorbing and insulating material according to the present invention.
6 is a cross-sectional photograph showing a sound absorbing and insulating material according to an embodiment of the present invention.
7 is a graph showing the results of a sound absorbing performance test conducted on a sound absorbing and insulating material according to the present invention and a conventional sound absorbing and insulating material.
8 is a view for explaining that the sound absorbing and insulating material according to the present invention has an improved noise blocking effect compared to the conventional sound absorbing and insulating material.
9A and 9B are views for explaining that the sound absorbing and insulating material according to the present invention has excellent resilience and moldability.
10 is a cross-sectional view illustrating a state of use of a sound absorbing and insulating material applied to a floor panel of an automobile.
11 is a view showing the arrangement of PET fibers in a sound absorbing and insulating material according to the prior art.

The present invention described below can apply various transformations and can have various embodiments, and specific embodiments are illustrated in the drawings and described in detail in the detailed description.

However, this is not intended to limit the present invention to specific embodiments, and it should be understood to include all modifications, equivalents, and substitutes included in the spirit and scope of the present invention. In describing the present invention, if it is determined that a detailed description of a related known technology may obscure the gist of the present invention, the detailed description thereof will be omitted.

The terms used in the present application are only used to describe specific embodiments, and are not intended to limit the present invention. The singular expression includes the plural expression unless the context clearly dictates otherwise. In the present application, terms such as “comprise” or “have” are intended to designate that a feature, number, step, operation, component, part, or combination thereof described in the specification exists, but one or more other features It should be understood that this does not preclude the existence or addition of numbers, steps, operations, components, parts, or combinations thereof.

Also, terms such as first, second, etc. may be used to distinguish and describe various components, but the components should not be limited by the terms. The above terms are used only for the purpose of distinguishing one component from another.

In addition, when at least two different embodiments are described in the present application, all or part of the components may be used by merging and mixing with each other even if there is no particular description within the scope not departing from the technical spirit of the present invention. .

The present invention relates to a sound absorbing and insulating material that can be used for noise reduction in automobiles, and a method for manufacturing the same, and more particularly, has a multi-layered structure including a fiber absorbing and insulating material layer having a horizontal arrangement structure and a fiber sound absorbing and insulating material layer having a vertical arrangement structure, and Provided is a sound absorbing and insulating material with a surface-treated nonwoven fabric attached to the surface to suppress dust generation and increase the uniformity of the surface.

1 is a cross-sectional view showing an embodiment of a sound absorbing and insulating material according to the present invention, which shows an example of a sound absorbing and insulating material comprising three layers: an upper layer, a lower layer, and an intermediate insertion layer. Similarly, the sound absorbing and insulating material of the present invention is characterized by laminating the surface-treated nonwoven fabrics 14 and 15 on the outer surface of the main sound absorbing and insulating material layer 10 having a multilayer structure.

2 is a cross-sectional view schematically illustrating the structure of a vertically arranged sound absorbing and insulating material layer included in the sound absorbing and insulating material of the present invention. The sound absorbing and insulating material of the present invention includes the vertically arranged sound absorbing and insulating material layer shown in FIG. There is another characteristic of the composition.

As shown in Fig. 1, the sound absorbing and insulating material of the present invention is laminated on the outer surface of the multi-layered fiber sound absorbing and insulating material main layer 10 including the vertically arranged sound absorbing and insulating material layers, and the sound absorbing and insulating material main layer 10 is laminated and attached. It is composed of at least one or more non-woven fabrics (hereinafter, referred to as surface-treated non-woven fabrics) 14 and 15.

The sound absorbing and insulating material of the present invention has the following two main characteristics.

First, in the sound absorbing and insulating material of the present invention, surface-treated nonwoven fabrics 14 and 15 are laminated and attached to one or both sides (up and down sides in the drawing) of the main sound absorbing and insulating material layer 10 (which is the surface of the sound absorbing and insulating material main layer).

These surface-treated nonwoven fabrics 14 and 15 are for suppressing the generation of dust from the sound absorbing and insulating material, and by attaching and finishing the thin surface treated nonwoven fabrics 14 and 15 to the outer surface of the sound absorbing and insulating material, generation of dust on the surface of the sound absorbing and insulating material is prevented in advance. This can be prevented, and the uniformity of the surface of the sound absorbing and insulating material can be improved.

As the surface-treated nonwoven fabrics 14 and 15, a nonwoven fabric having a minimum thickness of 05 mm and an areal density of 15 g/m 2 may be used, and as a preferred embodiment, a high melting point PET fiber having a fineness of 2 to 15 denier and 2 to 6 denier A nonwoven fabric composed of phosphorus low-melting PET fibers may be used.

The surface-treated nonwoven fabric is not only difficult to produce with an areal density of less than 15 g/m 2 due to production restrictions of current equipment, but also has a low surface tension due to too low areal density when it is less than 15 g/m, and the web is not formed evenly However, in the subsequent process, wrinkles and peeling may occur on the surface.

For this reason, the thickness must also have a minimum of 05 mm.

In order to attach the surface-treated nonwoven fabrics 14 and 15 and the sound absorbing and insulating material main layer 10, a heat-sealing method is applied as described below.

Second, the sound absorbing and insulating material layer having a vertically arranged layer structure is applied to a part of the structure of the multi-layered structure, that is, the sound absorbing and insulating material main layer 10 .

That is, in the sound absorbing and insulating material of the present invention, the main sound absorbing and insulating material layer 10 is a sound absorbing and insulating material having a structure in which horizontally arranged webs are stacked, that is, a sound absorbing and insulating material layer having a horizontally arranged layer structure (hereinafter, horizontally arranged sound absorbing and insulating material layers 12 and 13). It consists of a multi-layer structure in which a sound absorbing and insulating material having a structure in which the web is formed in multiple layers in a vertical arrangement, that is, a sound absorbing and insulating material layer having a vertically arranged layer structure (hereinafter referred to as the vertically arranged sound absorbing and insulating material layer 11) are laminated] .

In the embodiment of the three-layer structure shown in FIG. 1, the intermediate insertion layer of the sound absorbing and insulating material main layer 10 is composed of a vertically arranged sound absorbing and insulating material layer 11, and is stacked above and below the intermediate insertion layer. This is an example in which the upper and lower layers are composed of horizontally arranged sound absorbing and insulating material layers 12 and 13 .

In the illustrated embodiment, a sound absorbing and insulating material composed of a vertically arranged sound absorbing and insulating material layer 11 as an intermediate insertion layer and horizontally arranged sound absorbing and insulating material layers 12 and 13 as upper and lower layers is taken as an example. It is not limited to the three-layer sound absorbing and insulating material, and as long as it includes a vertically arranged sound absorbing and insulating material layer, the structure of the main sound absorbing and insulating material layer can be appropriately changed.

That is, it can be implemented in a two-layer stacked structure. In a sound absorbing and insulating material having such a two-layer stacked structure, the main sound absorbing and insulating material layer has a multilayer structure in which a horizontally arranged sound absorbing and insulating material layer and a vertically arranged sound absorbing and insulating material layer are stacked. will become

Of course, it is also possible to implement a structure of four or more layers.

As described above, the sound absorbing and insulating material of the present invention has a multi-layer structure of two, three or more layers, and a vertically arranged sound absorbing and insulating material layer is applied to a part of the layers. Since the vertically arranged sound absorbing and insulating material layers 11 have a multilayer structure in which they are mixed and stacked, a difference in areal densities between layers is exhibited.

That is, when manufacturing a sound absorbing and insulating material having a multilayer structure such as two or three layers, in the present invention, by applying the vertically arranged sound absorbing and insulating material layer 11 as a part of the layer, the difference in areal density between the layers can be increased. , it will be possible to improve the sound absorption performance through this.

First, as the horizontally arranged sound absorbing and insulating material layers 12 and 13, a normal horizontally arranged side surface used in sound absorbing and insulating materials is used. , produced by a conventional cotton manufacturing process, by mixing a low-melting-point fiber binder (LMF) and a high-melting-point fiber (SF) in a predetermined fineness ratio and weight ratio, stacking a thin nonwoven layer in a horizontal arrangement, and then thermally sealing it. .

More specifically, in order to produce a horizontally arranged cotton surface, as is well known, a step of opening after mixing a low-melting-point fiber binder and a high-melting-point fiber, pulling it out into a sheet-shaped fiber web, and horizontally arranging the fiber web It goes through a carding step that stacks up with

In addition, as a subsequent process, after a preheating step of drying the laminated web to a certain level in a pre-heater, drying and molding are performed by applying hot air in a heat bonding oven or heating chamber. After a heating step, the compression molding step is passed through a press roller to adjust the thickness, a cooling and thickness adjustment step is passed through a cooling roller to cool and adjust the final thickness, and the cutter cuts according to the standard step by step, etc.

In this manufacturing process, when heat is applied and then compressed, the fibers and the web layers of the cotton are bound up and down by the fused low-melting fiber binder, and at the same time, a sound absorbing and insulating material of a certain thickness is produced. As it melts, it serves to hold the fiber and web layers together.

In addition, the vertically arranged sound absorbing and insulating material layer 11 is a material in which a fibrous web (thin film) is stacked in a wave form in a vertical arrangement rather than a horizontal arrangement, and the structure is as shown in FIG. 2 .

The material of the vertical arrangement structure has superior elastic repulsive force compared to the material of the horizontal arrangement structure and is generally used in bed mattresses or women's cleaning pads. together with the material of the horizontal arrangement of

In the process of manufacturing the material of the vertical arrangement structure, the initial process is the same as the manufacturing process of the general cotton.

That is, after opening the fiber by mixing a low-melting-point fiber binder and a high-melting-point fiber, carding makes a thin web, and then a thin layer in the form of a web is supplied to a cylindrical device with a certain sawtooth shape, and the web supplied here (11a) is erected as illustrated in FIG. 2 by a sawtooth-shaped cylindrical device and folded closely at the same time to form a wave shape in which this shape is repeated as a whole.

Referring to FIG. 2 , the structure of the wave form in which the web 11a is repeatedly folded in a certain shape is shown, and the web 11a is schematically shown in a non-adherent state in the drawing to show that the web 11a is folded in the wave form, In fact, it is completely in close contact in a folded state, and when viewed from a cross-sectional view, the web 11a as a whole is seen as a vertically erected form, that is, a structure of a vertically arranged form.

3 is a perspective view illustrating a serrated cylindrical device 20 for making a sound absorbing and insulating material of a vertical arrangement structure in the present invention, and FIG. 4 is a serrated cylindrical device 20 shown in FIG. It is a cross-sectional view schematically showing a state in which the wave-shaped web 11a is made.

As shown in this figure, the web 11a is folded in a predetermined shape by the teeth 21, and the difference between the speed at which the web 11a is supplied to the teeth 21 and the speed that passes through the teeth 21 is The shape and thickness of the vertical arrangement are all determined by this.

In addition, in the material of the vertical arrangement structure, the nonwoven fabrics 11b and 11c that can weave the vertices of the waves are adhered to the upper or lower surfaces or both upper and lower surfaces of the vertically arranged structure folded in a wave shape, and the nonwoven fabrics 11b and 11c are By applying heat in the process of manufacturing a material with a vertical arrangement, it is bonded to the vertex of the wave of the web (thermal fusion bonding).

That is, after standing the web 11a in a wave-shaped vertical arrangement structure and folding it at the same time and stacking it in several layers, heat is applied in a state where the nonwoven fabrics 11b and 11c are placed on the upper and lower sides of the vertically arranged layer structure ( Preheating and melt processing) is molded, and at this time, the nonwoven fabrics 11b and 11c are adhered to each other by the heat applied, and a sufficient bond between the layers is made by the low-melting fiber binder.

By bonding the nonwoven fabrics 11b and 11c as described above, the shape of the vertically erected face can be kept constant, and even after receiving external weight, it can be easily restored without breaking its shape. (Repulsion elasticity is increased)

The surface of the vertically arranged structure manufactured in this way has the advantages of excellent elastic recovery and repulsion, and easy molding because the wave structure connected by the nonwoven fabrics 11b and 11c acts as a kind of spring.

The general face of a horizontal arrangement has problems such as peeling or falling off when attaching to a curved part, especially when attaching to a narrow and long part Peeling occurs easily, and the adhesive surface is peeled off.

However, since the face of the vertical arrangement does not peel off in any case and maintains its shape on the curved surface well, there is no problem in operation.

Accordingly, when the sound absorbing and insulating material of the present invention is attached to a portion of a structure having a large amount of curvature, it may be configured by using only a material having a vertical arrangement structure alone.

In this way, the sound absorbing and insulating material of the present invention has a multilayer structure in which the horizontally arranged sound absorbing and insulating material layers 12 and 13 and the vertically arranged sound absorbing and insulating material layer 11 are used together, and a vertically arranged sound absorbing and insulating material layer is formed on some layers of the multilayered structure. (11) is applied and constituted.

For example, in the case of a sound absorbing and insulating material having a three-layer structure, the horizontally arranged sound absorbing and insulating material layers 12 and 13 are used for the upper and lower layers, and the vertically arranged sound absorbing and insulating material layer 11 is applied for the intermediate insertion layer.

In addition, in the present invention, each of the sound absorbing and insulating material layers 11, 12, and 13 constituting the multi-layered sound absorbing and insulating material main layer 10 is a high-melting PET fiber having a fineness of 2 to 15 denier and a low-melting PET fiber having a fineness of 2 to 6 denier. The total thickness of the sound absorbing and insulating material main layer 10 having a multi-layer structure is 5 to 100 mm, and preferably, the thickness of the vertically arranged sound absorbing and insulating material layer 11, which is an intermediate interposed layer in the sound absorbing and insulating material main layer 10, is 1 to 100 mm. Make it 50mm.

In addition, the total areal density of the main sound absorbing and insulating material layer 10 having a multilayer structure is set to be 800 to 9000 g/m2, and preferably, the areal density of the vertically arranged sound absorbing and insulating material layer 11, which is an intermediate interposed layer in the sound absorbing and insulating material main layer 10, is 100 to 3000 g. Make it /m2.

In addition, the sound absorbing and insulating material main layer 10 having a multi-layer structure has a flow resistance value of 500 to 30000 Ns/m 3 .

In order to make a sound absorbing and insulating material layer having a multi-layer structure, a low weight of less than 800 g/m 2 does not exhibit satisfactory performance.

That is, in the multilayer structure, diffraction and resistance to incident sound can be increased only when the density difference due to the cross arrangement of the high-density sound absorbing and insulating material layer and the low-density sound absorbing and insulating material layer is expressed. It is difficult to produce products with

In addition, a certain thickness is required to make such a high-density and low-density layer. It is not possible to make three or more layers with a thickness of 5 mm or less, and the surface strength of the product is too high to be applied to the finished product molding process. hard to be satisfied

In addition, most of the weight of sound absorbing and insulating materials used in automobiles is less than 9000 g/m2 and less than 100 mm, so sound absorbing and insulating materials with a weight and thickness higher than this are inefficient because their frequency of use is low.

The three-layer sound absorbing and insulating material of the present invention is composed of a high-density horizontally arranged sound absorbing and insulating material layer (12, 13) and a relatively low-density vertically arranged sound absorbing and insulating material layer (11). Compared to the sound absorbing and insulating material of

Hereinafter, a process for manufacturing the sound absorbing and insulating material having a multilayer structure according to the present invention will be described as follows.

5 is a process chart for manufacturing a sound absorbing and insulating material according to the present invention. It has a three-layer structure in which the horizontally arranged sound absorbing and insulating material layers 12 and 13 are upper and lower layers and the vertically arranged sound absorbing and insulating material layer 11 is an intermediate interlayer. The process of manufacturing the sound absorbing and insulating material of

As shown in this figure, the surface-treated nonwoven fabrics 14 and 15 attached to the lower and upper surfaces and the vertically arranged sound absorbing and insulating material layer 11 for the intermediate insertion layer are separately manufactured and added during the process, and these are the horizontally arranged sound absorbing and insulating material for the lower layer and the upper layer. The horizontally arranged sound absorbing and insulating material is placed at a predetermined position in the manufacturing process, the materials are laminated as determined, and then the normal subsequent process is performed to complete the product.

As described above, the production of the product is carried out sequentially and continuously through the conventional manufacturing processes such as fiber opening (blending) and carding, the material input and lamination process, and the usual subsequent processes for producing the horizontally arranged sound absorbing and insulating material.

The manufacturing line shown in FIG. 5 is only an example for manufacturing the sound absorbing and insulating material according to the present invention, and the present invention is not limited thereto, and various modifications are possible within the scope of the technical spirit of the present invention.

When manufacturing a multi-layered sound absorbing and insulating material, particularly a three-layered sound absorbing and insulating material, the nonwoven fabrics 14 and 15 are adhered to the upper and lower skin layers, and a vertically arranged sound absorbing and insulating material layer 11 is added to the intermediate insertion layer. A more detailed description is as follows.

Since the sound absorbing and insulating material of the present invention is manufactured by inputting a surface-treated nonwoven fabric and a vertically arranged sound absorbing and insulating material during the manufacturing process of the horizontally arranged sound absorbing and insulating material, opening and carding are performed for each horizontally arranged sound absorbing and insulating material of the upper and lower layers, and in order to separately manufacture raw cotton Two faceting devices are deployed.

In order to manufacture the horizontally arranged raw cotton of the upper and lower layers, a low-melting-point PET fiber binder and a high-melting-point PET fiber are mixed at a predetermined fineness ratio and weight ratio in each device and opened (1st to 3rd mixing), and then a separate carding machine After manufacturing the web in the horizontal arrangement, the raw cotton of the upper and lower layers is produced separately.

In this way, the conventional process for each raw cotton is applied as it is.

And, when the raw cotton of the lower layer is made, it is transferred to a place where the surface-treated non-woven fabric for attaching to the lower surface is supplied, and the surface-treated non-woven fabric for attaching the lower surface is stacked on the raw surface of the lower layer (PET cotton in a horizontal arrangement).

Thereafter, the vertically arranged sound absorbing and insulating material is transferred to a location where the vertically arranged sound absorbing and insulating material is supplied, and the upper layer of raw cotton is piled on top of it. will give

As a result, a three-layer structure is made in which the horizontally arranged sound absorbing and insulating materials of the upper and lower layers and the vertically arranged sound absorbing and insulating material of the intermediate insertion layer are laminated.

After a preheating step of drying the laminated web to a certain level in a preheater, a heating step of drying and molding by applying hot air in a heat bonding oven or a heating chamber is performed, and then a compression roller ( It goes through a compression molding step of adjusting the thickness by passing it through a press roller, a cooling and thickness adjustment step of cooling and final thickness adjustment by passing it through a cooling roller, and a cutting step of cutting according to the standard by a cutter.

As described above, the sound absorbing and insulating material of the three-layer structure is subjected to preheating and melting, sufficient bonding between the layers by the low-melting PET binder is made, and in the last step, it is passed through a roller to obtain a desired thickness and is compression molded. It is cut to a certain length by the rear cutter and commercialized.

In the above process, the surface-treated nonwoven fabric and the horizontally arranged sound absorbing and insulating material are bonded by thermal fusion, and the horizontally arranged sound absorbing and insulating material and the vertically arranged sound absorbing and insulating material are also bonded by thermal fusion.

As another example, the horizontally arranged sound absorbing and insulating material may be adhered between the vertically arranged sound absorbing and insulating material using a chemical adhesive.

The present invention will be described in more detail based on examples. The present invention is not limited by the following examples.

(Examples and Comparative Examples)

As a comparative example, a sound absorbing and insulating material composed of a single layer of PET cotton with an areal density of 2800 g/m 2 and a thickness of 30 mm having a composition ratio of 60% SF 6De and 40% LMF 4De was prepared.

As an example, a sound absorbing and insulating material having a three-layer structure according to the present invention was manufactured, and a vertically arranged sound absorbing and insulating material having a thickness of 5 mm and an areal density of 400 g/m 2 was used as the intermediate interlayer, and the thickness of the upper and lower layers were 10 mm and 15 mm, respectively. , a horizontally arranged sound absorbing and insulating material having an areal density of 1100 g/m2 was used.

6 is a cross-sectional photograph showing a sound absorbing and insulating material according to an embodiment of the present invention.

On the other hand, in general, a sound absorbing and insulating material having a three-layer structure with a difference in areal density showed excellent sound absorption performance, so a comparative experiment was conducted by reducing the areal density.

As for the experimental method, the sound absorption coefficient of each sample was measured using a sample of 840 mm × 840 mm in a simple reverberation room, and the results are shown in FIG. 7 attached thereto.

Looking at the results of Figure 7, it can be seen that the sound absorption performance of the embodiment of the present invention is superior to that of the comparative example in the entire section (400 ~ 6300 Hz) in spite of reducing the weight by 200 g / m 2 .

8 is a view for explaining that the sound absorbing and insulating material according to the present invention has improved noise blocking effect compared to the conventional sound absorbing and insulating material. The main layer of the sound absorbing and insulating material of the present invention has a multi-layered arrangement (horizontal + vertical + horizontal).

In the multilayer structure of the present invention (right figure), since the layers having different densities and fiber arrangements are bonded, the surface impedance to sound at the bonding surface is greater than that of the conventional PET horizontal structure felt.

As such, surface resistance to sound exists in the contact surfaces of layers having different densities or different states. Sound is reflected on the contact surface by the resistance to sound, and eventually sound propagation is not performed well.

This is the same as the principle that sounds outside the water are not easily heard in the water. That is, the sound is reflected by the surface resistance of the water at the contact surface of the air and water, and the sound propagation is difficult due to the high density of water.

9A and 9B are views for explaining that the sound absorbing and insulating material according to the present invention has excellent resilience and moldability.

As shown in FIG. 9A , when the vertical arrangement PET is applied, the resilience of the sound absorbing and insulating material itself with respect to the load F is improved compared to the conventional horizontal arrangement application type.

In addition, as shown in FIG. 9B , the sound absorbing and insulating material of the present invention exhibits excellent formability in the case of a large mold step. As a result, the sound absorbing and insulating material has superior flexibility compared to the existing sound absorbing and insulating material, and has good formability due to its excellent flexibility. When applied to the double curved surface of the panel, it becomes very advantageous.

In this way, the sound absorbing and insulating material of the present invention is constructed by laminating a horizontally arranged sound absorbing and insulating material and a vertically arranged sound absorbing and insulating material. It is possible to obtain a more improved sound absorption performance while reducing it.

As described in detail above, according to the sound absorbing and insulating material having a vertical arrangement structure and the method for manufacturing the same according to the present invention, it is possible to prevent the short fiber PET from peeling off the surface by attaching a thin surface-treated nonwoven fabric to the surface and finishing it. It can prevent dust generation in advance, and has the effect of increasing the uniformity of the surface.

In addition, the high-density horizontally arranged PET sound absorbing and insulating material layer and the low-density vertically arranged PET sound absorbing and insulating material layer have a multi-layered structure in which they are mixed and laminated, thereby showing a difference in areal density between layers. The sound absorption performance has the effect of further improving.

In addition, the vertically arranged PET sound absorbing and insulating material newly used in the present invention has excellent elastic recovery and repulsion (having excellent resilience), does not peel off in any case, and by using the vertically arranged PET sound absorbing and insulating material, It has an additional effect compared to the conventional sound absorbing and insulating material composed only of horizontally arranged materials, such as ensuring matching properties and moldability.

On the other hand, the embodiments disclosed in the drawings are merely presented as specific examples to aid understanding, and are not intended to limit the scope of the present invention. It is apparent to those of ordinary skill in the art to which the present invention pertains that other modifications based on the technical spirit of the present invention can be implemented in addition to the embodiments disclosed herein.

10: Sound absorbing and insulating material main layer 11: Vertically arranged sound absorbing and insulating material layer
11a: web 11b, 11c: non-woven fabric
12: Horizontally arranged sound absorbing and insulating material layer (or vertically arranged sound absorbing and insulating material)
13: horizontally arranged sound absorbing and insulating material layer (or vertically arranged sound absorbing and insulating material)
14: surface treatment non-woven fabric for upper surface attachment
15: Surface treatment nonwoven fabric for attaching to the lower surface

Claims (9)

A sound absorbing and insulating material main layer having a multi-layer structure in which a plurality of fiber sound absorbing and insulating material layers are laminated, and a surface-treated nonwoven fabric attached to one or both surfaces of the sound absorbing and insulating material main layer, the main sound absorbing and insulating material layer is formed by forming several layers in a vertical arrangement with a web. A sound absorbing and insulating material having a vertically arranged structure comprising a vertically arranged sound absorbing and insulating material layer, the sound absorbing and insulating material comprising:
The sound absorbing and insulating material main layer has a three-layer structure, in which the intermediate insertion layer is composed of the vertically arranged sound absorbing and insulating material layer, and the upper and lower layers of the intermediate interposed layer are composed of horizontally arranged sound absorbing and insulating material layers having a structure in which a horizontal web is laminated,
The vertically arranged sound absorbing and insulating material layer has a wave shape stacked in a vertical arrangement by folding closely at the same time as the web is erected,
The vertically arranged sound absorbing and insulating material layer is a sound absorbing and insulating material having a vertically arranged structure in which a nonwoven fabric capable of weaving wave vertices is adhered to an upper surface, a lower surface, or both upper and lower surfaces of the vertically arranged structure in which a web is folded in a wave shape. A sound absorbing and insulating material main layer having a multi-layer structure in which a plurality of fiber sound absorbing and insulating material layers are laminated, and a surface-treated nonwoven fabric attached to one or both surfaces of the sound absorbing and insulating material main layer, the main sound absorbing and insulating material layer is formed by forming several layers in a vertical arrangement with a web. A sound absorbing and insulating material having a vertically arranged structure comprising a vertically arranged sound absorbing and insulating material layer, the sound absorbing and insulating material comprising:
Each sound absorbing and insulating material layer of the sound absorbing and insulating material main layer is composed of a high-melting PET fiber of 2 to 15 denier and a low-melting PET fiber of 2 to 6 denier,
The sound absorbing and insulating material main layer has a vertical arrangement structure having an overall thickness of 5 to 100 mm. 3. The method of claim 2,
The vertically arranged sound absorbing and insulating material layer of the sound absorbing and insulating material main layer has a vertically arranged structure having a thickness of 1 to 50 mm. A sound absorbing and insulating material main layer having a multi-layer structure in which a plurality of fiber sound absorbing and insulating material layers are laminated, and a surface-treated nonwoven fabric attached to one or both surfaces of the sound absorbing and insulating material main layer, the main sound absorbing and insulating material layer is formed by forming several layers in a vertical arrangement with a web. A sound absorbing and insulating material having a vertically arranged structure comprising a vertically arranged sound absorbing and insulating material layer, the sound absorbing and insulating material comprising:
The sound absorbing and insulating material main layer has an overall areal density of 800 to 9000 g/m2,
The vertically arranged sound absorbing and insulating material layer of the sound absorbing and insulating material main layer has a vertically arranged structure having an areal density of 100 to 3000 g/m2. A sound absorbing and insulating material main layer having a multi-layer structure in which a plurality of fiber sound absorbing and insulating material layers are laminated, and a surface-treated nonwoven fabric attached to one or both surfaces of the sound absorbing and insulating material main layer, the main sound absorbing and insulating material layer is formed by forming several layers in a vertical arrangement with a web. A sound absorbing and insulating material having a vertically arranged structure comprising a vertically arranged sound absorbing and insulating material layer, the sound absorbing and insulating material comprising:
The sound absorbing and insulating material main layer is a sound absorbing and insulating material having a vertical arrangement structure having a flow resistance value of 500 to 30000 Ns/m3. A sound absorbing and insulating material main layer having a multi-layer structure in which a plurality of fiber sound absorbing and insulating material layers are laminated, and a surface-treated nonwoven fabric attached to one or both surfaces of the sound absorbing and insulating material main layer, the main sound absorbing and insulating material layer is formed by forming several layers in a vertical arrangement with a web. A sound absorbing and insulating material having a vertically arranged structure comprising a vertically arranged sound absorbing and insulating material layer, the sound absorbing and insulating material comprising:
The surface-treated nonwoven fabric is a sound absorbing and insulating material having a vertical arrangement structure having a minimum thickness of 0.5 mm and an areal density of 15 g/m2. A sound absorbing and insulating material main layer having a multi-layer structure in which a plurality of fiber sound absorbing and insulating material layers are laminated, and a surface-treated nonwoven fabric attached to one or both surfaces of the sound absorbing and insulating material main layer, the main sound absorbing and insulating material layer is formed by forming several layers in a vertical arrangement with a web. A sound absorbing and insulating material having a vertically arranged structure comprising a vertically arranged sound absorbing and insulating material layer, the sound absorbing and insulating material comprising:
The surface-treated nonwoven fabric is a sound absorbing and insulating material having a vertical arrangement structure of high-melting PET fibers of 2 to 15 denier and low-melting PET fibers of 2 to 6 denier. (a) opening and carding a low-melting-point fiber binder and a high-melting-point fiber to prepare a raw cotton having a horizontally arranged structure in which a horizontal web is laminated;
(b) sequentially laminating the raw surface of the horizontal arrangement structure, the sound absorbing and insulating material of the vertical arrangement structure in which the web is formed in multiple layers in a vertical arrangement, and the surface-treated nonwoven fabric attached to the outer surface of one or both sides;
(c) Thereafter, subsequent processes including preheating, melting, pressing, and cutting are sequentially performed to form a multilayered sound absorbing and insulating material main layer in which a horizontally arranged sound absorbing and insulating material layer and a vertically arranged sound absorbing and insulating material layer are stacked, and the sound absorbing and insulating material main layer Completing a final sound absorbing and insulating material product composed of a surface-treated nonwoven fabric attached to one or both surfaces of the product;
A method of manufacturing a sound absorbing and insulating material having a vertical arrangement structure comprising:
9. The method of claim 8,
In the step (a), the raw surface of the horizontally arranged structure for the upper layer and the raw surface of the horizontally arranged structure for the lower layer are separately prepared,
In step (b), the raw cotton of the horizontal arrangement structure for the lower layer and the surface-treated nonwoven fabric for attaching the lower layer are laminated, and the sound absorbing and insulating material of the vertical arrangement structure is laminated thereon, and the raw surface of the horizontal arrangement structure for the upper layer and the surface-treated nonwoven fabric for attaching the upper surface are laminated thereon. are sequentially stacked,
A method of manufacturing a sound absorbing and insulating material having a vertically arranged structure in which the sound absorbing and insulating material main layer of the final sound absorbing and insulating material product is manufactured in a three-layer structure consisting of an upper layer, an intermediate insertion layer, and a lower layer of a sound absorbing and insulating material layer.

Images