JP5350982B2 - Ventilation duct, components thereof, and manufacturing method thereof - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a ventilation duct suitable for performing the press molding of nonwoven fabric, and its constituent member to enhance the formability of the nonwoven fabric when performing the press forming of a nonwoven fabric member used for the ventilation duct. <P>SOLUTION: The constituent member 2 of the ventilation duct 1 includes the nonwoven fabric containing thermoplastic resin fiber and shaped by press working. In the constituent member, resin masses G formed by melting the thermoplastic resin fiber on a surface through a step of selectively heating the surface of the nonwoven fabric are granularly distributed on at least one surface of the nonwoven fabric, and the surface of the nonwoven fabric with the masses G distributed thereon is exposed to the surface of the constituent member 2 of the ventilation duct. <P>COPYRIGHT: (C)2011,JPO&amp;INPIT

Description

The present invention relates to a ventilation duct that allows air to flow inside a duct formed of a synthetic resin or the like. In particular, the present invention relates to a ventilation duct in which a part of the duct wall is provided with air permeability, a component member thereof, and a manufacturing method thereof.

Ventilation ducts are used in particular as part of a series of duct systems such as an intake system for an internal combustion engine for automobiles, an air conditioning system, and a cooling air blowing system. In such a duct system, a duct made of a non-breathable material is generally used for the duct wall. For this reason, noise caused by an engine, a fan, a motor, or the like as noise sources propagates in the duct, Since air column resonance that occurs in the system occurs, it has long been desired to reduce noise.

Technologies that reduce the noise that propagates through the duct system have been developed and applied, such as those that provide a chamber for expanding the diameter and those that provide a resonance silencer such as a Helmholtz resonator. A technique called so-called porous duct has been developed in which a part having air permeability is provided in a part of a duct wall to prevent air column resonance of the duct system and to reduce noise propagating through the duct.

As a porous duct having such a function, a technique as described in Patent Document 1 is known. In this technology, a hole is formed in a part of a non-breathable duct wall, and a porous material such as a non-woven fabric having an appropriate breathability is attached so as to cover these holes, and the duct internal space and external space are separated. In the porous duct described in Patent Document 1, a small tube portion protruding from the wall surface of the duct body is provided, and the nonwoven fabric is heated at the opening at the tip of the small tube portion. It is welded. In such a duct, by adjusting the air permeability of the porous material, it is possible to reduce noise propagating through the duct system while preventing the occurrence of air column resonance occurring in the duct system, and It is easy to mount, and further, the effect that the ventilation resistance of the duct can be reduced is obtained.

Patent Document 2 discloses an intake pipe in which at least a part of a pipe wall is formed from a molded body made of a nonwoven fabric in an intake pipe for an automobile engine. It is described that the duct is three-dimensionally formed into a half-cut shape by hot press molding.

JP 2001-323853 A JP 2000-73895 A

In a porous duct, when a non-woven member is used as a part of a ventilation duct as described in Patent Document 1 and Patent Document 2, a large amount of air does not leak from the non-woven fabric part, or an appropriate sound deadening In order to give characteristics or to give an appropriate rigidity and strength to the nonwoven fabric member, it is common to shape the nonwoven fabric by pressing.

However, when the non-woven fabric is press-molded, the non-woven fabric may be stretched and thinned in the press mold, and the desired non-woven fabric ventilation characteristics and rigidity / strength may not be obtained. It is difficult to increase production efficiency and yield. Also, especially when molding non-woven members shaped into complex three-dimensional shapes of ducts, there are many cases where non-woven fabrics tear in the press mold, making it impossible to form the non-woven members. There is a need to improve the formability during the process.

Accordingly, an object of the present invention is to improve the formability of a nonwoven fabric when a nonwoven fabric member used for a ventilation duct is press-molded, and to provide a ventilation duct suitable for press-molding with a nonwoven fabric and its components. There is to do.

As a result of intensive studies, the inventors have found that the use of a non-woven material having a specific surface prevents the non-woven fabric from being pulled and stretched by a press die, and the above problem is solved. Completed the invention.

The present invention includes a non-woven fabric containing thermoplastic resin fibers, and is a constituent member of a ventilation duct in which the non-woven fabric is shaped by press working, and at least one surface of the non-woven fabric is selectively heated on the surface thereof Through the process, the resin mass formed by melting the thermoplastic resin fibers on the surface is distributed in granular form, and the surface of the nonwoven fabric on which the mass is distributed is exposed on the surface of the ventilation duct component. component der ventilation duct Ru.

Further, in the ventilation duct component of the present invention, a plurality of nonwoven fabrics are laminated and shaped by press working, and at least one of the pairs of surfaces facing each other when the adjacent nonwoven fabrics are laminated, the nonwoven surface with lumps of the resin are distributed to the other surface of the nonwoven fabric, the mass of the resin is Ru is so not distributed (claim 1).
Moreover, this invention is an air duct containing the said air duct structural member (Claim 2 ).

The present invention also relates to a method for producing a nonwoven fabric ventilation duct component, wherein the surface of the nonwoven fabric containing thermoplastic resin fibers is selectively heated to melt the thermoplastic resin fibers on the nonwoven fabric surface, The first step of forming and distributing a lump of the material in a granular form on the surface of the non-woven fabric, the non-woven fabric surface obtained by distributing the lump of resin in a single layer or by laminating with another non-woven fabric in a single layer A vent duct configuration including a second step of supplying into a press die that has been opened so as to face at least one of the press dies, and a third step of closing and pressurizing the press die to shape the nonwoven fabric. A member manufacturing method (claim 3 ).

Furthermore, in the method for manufacturing a ventilation duct component according to the present invention, in the second step, a plurality of non-woven fabrics are stacked and supplied to the press die, and the non-woven fabrics stacked adjacent to each other are opposed to each other. In at least one set, the resin lump is distributed on one nonwoven fabric surface, and the nonwoven fabric is laminated so that the resin lump is not distributed on the other nonwoven fabric surface. Preferred (claim 4 ).

According to the invention of claim 1 or claim 3, the surface in which the lump of resin is distributed in a granular form on the nonwoven fabric surface is opposed to at least one of the press dies when the press molding is performed. It is possible to prevent the nonwoven fabric material from being stretched and thinned or torn and to improve the press formability.

Furthermore, as specified in claim 1 or claim 4 , a set of opposing surfaces of the nonwoven fabrics laminated to each other, one side being a surface on which the lump of resin is distributed in a granular form on the nonwoven fabric surface, the other is said When configured to be a surface in which the lump of resin is not distributed, the laminated nonwoven fabrics are less likely to slip from each other, further improving the effect of preventing elongation and tearing of the nonwoven fabrics, and further improving press formability. The effect is obtained.
Moreover, the ventilation duct of Claim 2 can enjoy the effect of invention of Claim 1.

It is a perspective view which shows the external appearance of the ventilation duct of 1st Embodiment of this invention. It is sectional drawing which shows the XX cross section of the ventilation duct of 1st Embodiment. It is a schematic diagram which shows the manufacturing process of the ventilation duct structural member of 1st Embodiment of this invention. It is a photograph which shows the state in which the lump of substantially spherical resin is distributed granularly on the nonwoven fabric surface. It is a photograph which shows the state in which the flat plate-shaped resin lump is distributed granularly on the nonwoven fabric surface. It is a photograph which shows the state of the normal nonwoven fabric surface where the lump of resin is not distributed. It is sectional drawing which shows the cross section of the ventilation duct of 2nd Embodiment of this invention. It is sectional drawing which shows the cross section along the duct longitudinal direction of a part of ventilation duct of 3rd Embodiment of this invention. In the manufacturing process of the ventilation duct constituent member of the present invention, it is a variation of a nonwoven fabric (laminated body) used for press molding.

Hereinafter, embodiments of the present invention will be described with reference to the drawings. However, the present invention is not limited to the individual embodiments shown below, and the embodiments can be modified. A ventilation duct 1 according to the first embodiment of the present invention shown in FIGS. 1 and 2 is a ventilation duct 1 used for sending cooling air for cooling a battery of a hybrid vehicle or an electric vehicle. 1 is a perspective view, and FIG. 2 is a cross-sectional view taken along line XX. The ventilation duct 1 is a hollow duct member in which a pair of half-broken bodies 2 and 3 are integrated by a covering body 4 at an end portion thereof, and the covering body 4 is a half-cracked body 2 as shown in FIG. , 3 is formed along the end edges of the half-cracked bodies 2 and 3 so as to wrap around the end edges to be joined. Openings 11 and 12 connected to other duct members, connection members, battery cases, blower fan cases and the like are provided on one side and the opposite side of the ventilation duct 1. The ventilation duct 1 is incorporated in a battery cooling system, and is used so that, for example, battery cooling air flows through the opening 12 so that air flowing into the duct from the opening 11 flows out of the opening 12. .

The half-cracked bodies 2 and 3 which are constituent members of the ventilation duct 1 are members formed by shaping a nonwoven fabric material by press molding. In the present embodiment, as will be described later, three non-woven fabrics are laminated and subjected to press molding, thereby forming half-broken bodies 2 and 3 shaped into a monaca shape that constitutes substantially half of the ventilation duct. . On the surfaces of the half-cracks 2 and 3, resin lumps G formed by heat treatment to be described later are distributed in a granular form. In this embodiment, the lump G of resin is distributed on both sides of the inner surface of the duct and the outer surface of the duct.

The resin lump G distributed on the nonwoven fabric surfaces of the half-cracks 2 and 3 will be described in detail. This resin lump G is made of a fiber material containing a thermoplastic synthetic resin fiber, with a flame, thermal radiation (for example, an infrared heater), etc., against a nonwoven fabric produced through a known carding process, laminating process, needle punching process, etc. It is a lump of resin formed on the surface of the nonwoven fabric by selectively heating the surface of the nonwoven fabric. When the nonwoven fabric surface is selectively heated, the thermoplastic resin fibers melt only near the nonwoven fabric surface, and the molten resin aggregates into a substantially spherical shape. When cooled in this state, the molten fiber resin is substantially spherical. A lump is formed, and the lump is distributed in a granular form on the surface of the non-woven fabric, and a non-woven fabric that is an ordinary non-woven fabric is obtained inside the non-woven fabric.

Such a nonwoven fabric can be obtained by adjusting the degree and time of heating and cooling when the nonwoven fabric surface is selectively heated, and is preferably produced continuously by providing a heating device on the nonwoven fabric production line. be able to. If the heating time is too long, the fiber will melt too much and the melted resin will continue and the nonwoven fabric surface will become a film or plate. In that case, the heating level will be reduced or the heating time will be shortened. In other words, the molten resin mass is adjusted so as to be distributed in a granular form on the nonwoven fabric surface.

This heat treatment can be performed independently for each of the front and back sides of the nonwoven fabric, and it is also possible to distribute a lump of resin on both sides of the front side and the back side in a granular manner. It is possible to use a normal nonwoven fabric surface so that the lump of resin is distributed in a granular form.

Moreover, after performing the said heat processing on a nonwoven fabric and forming the lump of substantially spherical resin on the nonwoven fabric surface, you may heat-apply further. When heat pressing is performed with the resin lump softened immediately after the heat treatment, the resin lump is crushed and becomes flat and distributed in a granular form on the nonwoven fabric surface.
The resin lump G distributed in a granular form on the surfaces of the half-cracks 2 and 3 according to the embodiment of the present invention is a substantially spherical or flat plate-like resin lump formed on the nonwoven fabric surface by the heat treatment as described above.

4 and 5 are magnified photographs of the nonwoven fabric surface showing a state in which the resin lump G is distributed in a granular manner on the nonwoven fabric surface, and are photographs taken with a power high scope apparatus. FIG. 4 shows the resin mass G distributed as a substantially spherical mass, and FIG. 5 shows the resin mass G distributed as a flat plate-shaped mass. The fiber structure of the nonwoven fabric remains. Further, in FIG. 4, it was observed that the molten resin became a substantially spherical lump (including a spherical shape, a teardrop shape, and a spindle shape) and was distributed in a granular manner on the surface of the nonwoven fabric. It is observed that the resin is flattened into a plate-like resin lump and is distributed in a granular form on the surface of the nonwoven fabric. FIG. 6 shows an enlarged photograph of a normal nonwoven fabric surface in which the resin lump G is not distributed granularly on the surface, and a structure in which constituent fibers of the nonwoven fabric are entangled is observed on the normal nonwoven fabric surface.

The configuration and properties of a nonwoven fabric that can be preferably used for forming the half-cracks 2 and 3 of the present embodiment will be described. As the nonwoven fabric, a nonwoven fabric made of synthetic resin fibers can be preferably used, and examples of the synthetic resin fibers include PET resin fibers, polypropylene resin fibers, and thermoplastic resin fibers such as polyamide resin fibers and polyester resin fibers. In particular, it is important that thermoplastic resin fibers are contained in the nonwoven fabric in order to distribute the lump of resin on the nonwoven fabric surface in a granular manner by the heat treatment described above. In addition to thermoplastic resin fibers, non-woven fabrics contain other fiber materials such as natural fibers (cotton, hemp, pulp), semi-natural fibers (such as rayon fibers), metal fibers, glass fibers, carbon fibers, and rock wool. You may do it.

As the thermoplastic resin fibers, resin fibers having a core-sheath structure made of thermoplastic resins having different melting points may be used. Moreover, it is good also as a nonwoven fabric which blended the thermoplastic resin fiber from which melting | fusing point differs. In particular, if a nonwoven fabric blended with thermoplastic resin fibers having different melting points is used in the practice of the present invention, in the heat treatment step described above, only the low melting point fibers melt and become a lump of resin on the nonwoven fabric surface. The melting point fiber maintains the form of the fiber, and it is easy to obtain a nonwoven fabric in which a lump of resin is distributed on the surface in a granular form. Moreover, the nonwoven fabric material in which the low-melting fiber and the high-melting fiber are mixed is improved in workability at the time of hot press processing described later, and it becomes easy to fix the uneven shape of the press-formed product and adjust the air permeability.

The non-woven fabric may be a single-layer non-woven fabric or a multi-layer non-woven fabric. In addition, for nonwoven fabrics, acrylic resins, styrene resins, phenolic resins, epoxy resins, vinyl acetate resins, etc. are used for the purpose of improving the shape retention of nonwoven fabrics and adjusting the breathability of nonwoven fabrics. It can be used by impregnating a binder resin containing a resin component.

In the ventilation duct 1 and the half-cracked bodies 2 and 3 which are the constituent members of the present embodiment, the non-woven fabric material in which the heat treatment is performed on the non-woven fabric so that the resin mass G is distributed in a granular manner on the non-woven fabric surface. (A1, A2, A3) is shaped by press molding. As a result, the resin lump G formed by the heat treatment is formed on the surface of the press-molded nonwoven fabric molded body (half-cracked bodies 2, 3). Are distributed in granular form.

The manufacturing method of the said air duct 1 and its structural member (half crack bodies 2, 3) is demonstrated. The half-broken bodies 2 and 3 are manufactured through a non-woven fabric preparation process, a supply process to a press die, a press molding process, and a cutting / finishing process as necessary. Then, the obtained half-cracked bodies 2 and 3 are set in an injection mold, and the covering material 4 wraps the edge portion to which the half-cracked bodies 2 and 3 are bonded by so-called overmolding. The air duct 1 is manufactured by injection molding the resin material and integrating the half cracks 2 and 3.

Each step will be described in detail below.
(Nonwoven fabric preparation process)
A non-woven fabric to be subjected to press molding is prepared. A non-woven fabric containing thermoplastic resin fibers is produced by a known production method, and as described above, the surface of the non-woven fabric is selectively heated to melt the thermoplastic resin fibers on the non-woven fabric surface as described above. To obtain a non-woven fabric with a granular distribution. Since nonwoven fabrics may be laminated and press molded, nonwoven fabrics with different fiber composition, thickness, basis weight, and surface condition may be prepared as necessary.

(Supply process to press mold)
The non-woven fabric obtained in the previous step is cut into a predetermined size suitable for press treatment.
And a some nonwoven fabric is laminated | stacked as needed. The nonwoven fabric can be subjected to press molding as a single layer, and in that case, it is not necessary to laminate the nonwoven fabric. That is, the nonwoven fabric to be subjected to press molding may be in a single layer state or a laminated state, but it is necessary to at least include the nonwoven fabric in which the lump of resin is distributed in a granular form on the nonwoven fabric surface.
When laminating, the non-woven fabric is laminated and arranged so that the non-woven fabric surface in which the lump of resin G is distributed is opposed to at least one mold surface of the press dies P1, P2 opened in the vertical direction. .

In this embodiment, two non-woven fabrics (A1, A2) in which resin lump G is distributed in granular form only on one side and one non-woven fabric (A3) in which resin lump G is distributed in granular form on both sides are laminated, The lowermost layer is a nonwoven fabric A3 in which resin lump G is distributed in granular form on both sides, and the intermediate layer and the uppermost layer are nonwoven fabrics A2 and A1 in which resin lump G is distributed in granular form only on one side, respectively. Are laminated so that the surface in which the particles are distributed in a granular manner is on the upper side (FIG. 3A).

As a result, in the laminated nonwoven fabric laminate AA, the resin mass G is distributed in a granular form on the uppermost surface and the lowermost surface. Furthermore, in the nonwoven fabric laminated | stacked adjacently, the group of the nonwoven fabric surface made to oppose each other (namely, the group of the lower surface of nonwoven fabric A1 and the upper surface of nonwoven fabric A2, and the group of the lower surface of nonwoven fabric A2 and the upper surface of nonwoven fabric A3 ), The lump G of resin is distributed on the surface of one non-woven fabric in a granular form, and the non-woven fabric surface is a normal non-woven fabric surface on which the lump of resin is not distributed.

The entire nonwoven fabric laminate AA is heated while maintaining this laminated state. Oven heating is preferably used for heating, and it is preferable to uniformly heat the entire nonwoven fabric laminate. The heating temperature is a temperature suitable for press molding and is preferably a temperature at which at least a part of the thermoplastic resin fibers contained in the nonwoven fabric laminate AA is softened.
And the nonwoven fabric laminated body AA heated to predetermined temperature is supplied and arrange | positioned inside the press type | molds P1 and P2 which were opened (FIG.3 (b)).

(Press molding process)
The press dies P1, P2 are closed and a predetermined pressure is applied. By this step, the nonwoven fabric laminate AA becomes a nonwoven fabric molded body B having a shape that matches the shape of the cavity provided in the press mold (FIG. 3C). By passing through the pressing step, the lump of resin distributed on the surface of the nonwoven fabric may become a flat plate. Further, when the nonwoven fabric laminate AA is heated at a relatively low temperature and is heated and pressed at such a temperature that the lump of resin distributed on the nonwoven fabric surface does not soften, The resin lump G distributed on the nonwoven fabric surface may be distributed on the surface of the nonwoven fabric molded product B while maintaining the substantially spherical shape before pressing.

It is particularly advantageous to keep the air permeability low when the resin lump is distributed on the surface of the nonwoven fabric molded body by press molding. In that case, even if it is a nonwoven fabric with a comparatively low fabric weight, the air permeability can be suppressed effectively and the ventilation duct member excellent in the acoustic characteristic can be obtained.

(Cut and finishing process)
The press-molded nonwoven fabric molded body B is taken out from the press mold, and unnecessary portions are cut with cutters C, C, etc. as required (FIG. 3D). If drilling is necessary, it can be performed at this stage. In the present embodiment, an unnecessary portion of the side portion of the half-cracked body is cut off, and portions that become the opening portions 11 and 12 of the ventilation duct 1 are cut. Through these steps, the constituent members of the ventilation duct 1 that is one of the embodiments of the present invention (that is, the half-cracked members 2 and 3) can be manufactured.
Depending on the shape of the component, such as a simple planar shape, the cutting / finishing process may not be necessary. Further, the cutting step can be performed simultaneously with press molding using a press die.

(Ventilation duct assembly process)
Through the above steps, the obtained ventilation duct constituent members (in the present embodiment, half-cracks 2 and 3) are assembled to manufacture the ventilation duct 1. In the present embodiment, the half cracks 2 and 3 are integrated by so-called overmolding, the half cracks 2 and 3 are set in an injection mold, the mold is closed, The material of the covering material is injection-molded so that the edge portion to which 3 is to be joined is wrapped with the covering material 4, and the half-cracks 2 and 3 are integrated to complete the ventilation duct 1.

Advantageous actions and effects in this embodiment will be described.
According to this embodiment, using a nonwoven fabric material (nonwoven fabric laminate) having a special surface property that a lump of resin is distributed in a granular form on the surface of the nonwoven fabric, the surface of the nonwoven fabric in which the lump of resin G is distributed in a granular form and a press Since press molding is performed so that at least one of the molds is opposed to the mold, the nonwoven fabric (laminated body) is stretched and thinned during the press molding, and it is torn, resulting in defective molding. It is suppressed / prevented.

The shape of the nonwoven fabric press-molded body that becomes the ventilation duct constituent member is not particularly limited, and can be various shapes such as a cylindrical shape, a rectangular tube shape, a hat shape, a dome shape, etc. In addition to the simple shape that can be formed by bending a flat nonwoven material, it is a drawing process in press forming such as a dome shape or bag shape, and a complicated three-dimensional structure that requires expansion and contraction of the nonwoven material during press forming. In some cases, the present invention can improve the formability of press molding particularly effectively in forming a ventilation duct component having a complicated three-dimensional shape that makes it difficult to press the nonwoven fabric.

Although the press formability is improved, that is, the mechanism by which the nonwoven fabric (laminate) stretches and becomes thin and does not break is not necessarily quantitatively understood, the lump of resin on the surface of the nonwoven fabric is granular. Due to the distribution, the opposing press mold and the slip are improved,
It is presumed that the heat treatment for distributing the lump of resin on the surface of the nonwoven fabric in a granular manner causes the surface of the nonwoven fabric to melt slightly, resulting in an increase in the degree of bonding of the nonwoven fabric surface.

Therefore, from the viewpoint of improving the press formability, as shown in the present embodiment, the non-woven fabric surface in which the lump of resin G is distributed in granular form is opposed to both sides of the press molds P1 and P2. preferable. However, as in the embodiments described later (for example, FIGS. 9B and 9C), the nonwoven fabric surface in which the lump of resin is distributed in granular form only on one side of the press mold may be opposed. In this case, in particular, it is preferable to face the nonwoven fabric surface in which the lump of resin is distributed in a granular form on the side where the nonwoven fabric is easily caught on the press mold.

In addition, when laminating non-woven fabrics to be subjected to press molding as in this embodiment, a lump of resin formed by heat treatment is distributed in granular form on one non-woven fabric surface in a set of non-woven fabric surfaces laminated and opposed to each other. When the other nonwoven fabric surface is laminated so as to have a normal nonwoven fabric surface in which such a lump of resin does not exist, an effect that the laminated nonwoven fabrics are less likely to be displaced from each other occurs, and the nonwoven fabric laminate is pressed. Elongation, tearing, and generation of wrinkles are further suppressed and prevented, and it becomes easier to obtain a molded product having a uniform thickness and density, thereby further improving press formability.

This effect of preventing the laminated nonwoven fabric from being displaced is that the surfaces of the nonwoven fabric surfaces that are laminated and opposed to each other are both surfaces in which the lump of resin formed by heat treatment is distributed in granular form, or conversely It does not occur when both surfaces are normal nonwoven fabric surfaces where no resin lump exists, and the surface where the resin lump is distributed granularly by heat treatment and the normal nonwoven fabric surface where no resin lump exists are opposite This is an effect that appears only when the nonwoven fabric is laminated.
In the above-described embodiment, all the sets of non-woven fabric surfaces facing each other in the non-woven fabric laminated adjacent to each other are such a combination, and this is a particularly preferred embodiment. However, this need not be the case (for example, FIGS. 9C, 9D, 9E, 9F).

Moreover, if the heat treatment and press molding conditions are adjusted so that the lump of resin on the nonwoven fabric surface becomes a flat plate and dispersed, the air permeability of the nonwoven fabric molded body can be effectively reduced. Such a treatment may be performed by adding a pressing step to the step of performing a heat treatment for forming a lump of resin on the surface of the nonwoven fabric, or may be performed by a pressing step (FIG. 3 (c)) of the nonwoven fabric molded body B. good.

In the ventilation duct of this embodiment or the so-called porous duct as described in Patent Document 1 and Patent Document 2, the air permeability of a portion having air permeability (that is, a portion of a porous body such as a nonwoven fabric molded body) is compared. Otherwise, the noise prevention effect often decreases. Therefore, the preferable level of air permeability of the nonwoven fabric molded body (half-cracked bodies 2, 3) is measured in a method based on the Gurley test method specified in JIS P8117, and is in the range of about 1 to 100 seconds / 300 cc. More preferably, it is the range of about 5-40 seconds / 300cc. In order to achieve such a relatively low air permeability, the air permeability is usually lowered by increasing the basis weight, but in the air duct component member of this embodiment, the resin distributed on the nonwoven fabric surface By forming the lump into a flat plate shape, a nonwoven fabric molded article having a preferable air permeability can be produced with a relatively low basis weight, and particularly preferable characteristics can be easily obtained.

The present invention is not limited to the above embodiment, and can be implemented with various modifications. Although other embodiments of the present invention will be described below, in the following description, portions different from the above embodiment will be mainly described, and the same portions will be denoted by the same reference numerals and detailed description thereof will be omitted. .

In the description of the above embodiment, the embodiment has been described in which the ventilation duct is used as a blower duct of a battery cooling system such as an electric vehicle. However, the use of the ventilation duct is not limited thereto. For example, the ventilation duct of the present invention can be used as a ventilation duct for constituting a part of a ventilation path of an intake system for supplying air to an internal combustion engine such as an automobile engine. Moreover, in air-conditioning systems, such as an air conditioner, it can be used also as a ventilation duct for comprising a part of ventilation path for blowing air.

7 and 8 show another embodiment of the ventilation duct and its constituent members according to the present invention. For example, FIG. 7 shows a cross-section of the second embodiment of the ventilation duct of the present invention. In this embodiment, the ventilation duct is half-cracked by press-molding a nonwoven fabric material and forming a half-cracked monaca-like nonwoven fabric molded body. Although the point which uses the body 5 is the same as that of 1st Embodiment, in this embodiment, the half crack body 6 of the other side is formed by blow molding or injection molding with the non-breathable synthetic resin material (for example, polyamide resin). The half-cracked body 5 and the non-breathable half-cracked body 6 are different in that they are integrated by adhesion. Moreover, in this embodiment, the lump G of resin is distributed granularly on the nonwoven fabric surface only on the duct outer surface side of the half-cracked body 5 made of nonwoven fabric.

Or in FIG. 8, although the cross section along the duct axial direction of a part of duct of 3rd Embodiment of the ventilation duct of this invention is shown, in this embodiment, like the duct of patent document 1, A non-woven fabric structural member 7 formed by pressing a non-woven fabric is welded and integrated at the end of a cylindrical opening 81 provided in a part of a duct body member 8 formed of a non-breathable material such as polypropylene resin. In addition, on the duct outer peripheral surface side of the nonwoven fabric component 7, the resin lump G is distributed in a granular manner on the nonwoven fabric surface.

Thus, the form in which the present invention is applied to the ventilation duct is not particularly limited, and can be widely applied to any ventilation duct including a member obtained by press-molding a nonwoven fabric. And, regarding the components of the ventilation duct other than the non-woven fabric component, it is clear that widely known techniques can be adopted, and if there is a portion of non-breathable material in the ventilation duct, that portion is made of thermoplastic resin. It can be formed by injection molding or blow molding, or can be composed of a metal plate or the like. In addition, not only the overmolding method described in the first embodiment but also the insert molding, two-color molding, adhesion, and welding are used for joining the nonwoven fabric structural members (5, 7) and the non-breathable structural members. Well-known techniques such as fitting, engagement, and locking by a locking piece can be used.

FIG. 9 shows a variation when the nonwoven fabric (laminated body) is supplied to the press mold in the press molding step of the nonwoven fabric molded body B (FIG. 3). There is an improvement effect.

9 (a) and 9 (b) are examples in which the nonwoven fabric is subjected to press molding in a single layer. In FIG. 9 (a), the nonwoven fabric in which the lump of resin is distributed in granular form on both sides is shown in FIG. 9 (b). Is an example in which a non-woven fabric in which a lump of resin is distributed in granular form on one side (upper surface) is subjected to a pressing process in a single layer.

FIG. 9C is an example in which three non-woven fabrics are laminated and subjected to press molding. The lowermost layer and the uppermost layer are non-woven fabrics in which a lump of resin is distributed in granular form on one side (upper surface). Is an example in which a normal nonwoven fabric in which no lump of resin is distributed is laminated and used for the pressing step. As shown in this example, when a nonwoven fabric is laminated and used for press molding, the laminated nonwoven fabric should contain a normal nonwoven fabric in which no lump of resin is distributed on the nonwoven fabric surface. You can also.

FIG. 9 (d) is an example in which four nonwoven fabrics are laminated and subjected to press molding. The lowermost layer and the uppermost layer are nonwoven fabrics in which a lump of resin is distributed in granular form on both sides, and the second and third layers. The layer is an example in which a normal nonwoven fabric in which no lump of resin is distributed is laminated and used for the pressing step.

FIG. 9E is an example in which two nonwoven fabrics are laminated and subjected to press molding. The lower layer is a nonwoven fabric in which a lump of resin is distributed on one side (lower surface), and the upper layer is a single side ( This is an example in which a non-woven fabric in which a lump of resin is distributed in a granular form is laminated on the upper surface) and subjected to a pressing process.

FIG. 9F is an example in which two non-woven fabrics are laminated and subjected to press molding, and in the lower layer and the upper layer, a non-woven fabric in which a lump of resin is distributed on both sides is laminated and subjected to a pressing process. .

In any of the examples shown in FIGS. 9A to 9F, the lump of resin is distributed in granular form on any of the nonwoven fabric surfaces facing the press mold, thereby improving the press formability. There is.

In addition, when the nonwoven fabrics are laminated, one set of opposing surfaces of the nonwoven fabrics laminated adjacent to each other is a surface in which the lump of resin is distributed in granular form, and the other is the distribution of resin lump in granular form It is preferred that it be a normal non-woven surface, but this is not necessarily the case, as shown in these lamination variations, the set of opposing surfaces of the non-woven fabric laminated adjacent to each other The surface may be a surface on which resin lumps are distributed in granular form, or both surfaces may be a normal nonwoven fabric surface on which resin lumps are not distributed in granular form.

In addition, the material laminated when it is subjected to press molding is not limited to the nonwoven fabric alone, and may be laminated with woven fabric, resin foam, wire mesh, etc. in order to improve the characteristics of the molded product. good.

The ventilation duct and its constituent members of the present invention can be used in a ventilation duct (such as an intake duct, an air conditioner duct, and a blower duct) that allows air to flow therethrough. According to the ventilation duct of the present invention, a duct having desirable characteristics can be efficiently manufactured, and the industrial utility value is high.

1 Ventilation ducts 2, 3 Half-broken body (Ventilation duct components)
4 Coating material G Resin lump AA Non-woven fabric laminate A1, A2 Non-woven fabric P1, P2 Press mold B Non-woven fabric molded product C Cutter 5 Half-broken body (ventilating duct component)
6 Non-breathable half-broken body (ventilation duct component)
7 Breathable member (Venting duct component)
8 Non-breathable duct members (ventilating duct components)

Claims (4)

While including a non-woven fabric containing thermoplastic resin fibers, the non-woven fabric is a constituent member of the ventilation duct formed by pressing,
At least one surface of the non-woven fabric has a resin mass formed by melting the thermoplastic resin fibers on the surface through a process of selectively heating the surface in a granular form,
Rutotomoni surface of the nonwoven fabric in which the mass distribution is to be exposed on the surface of ventilation duct components,
The component member is formed by pressing a plurality of non-woven fabrics laminated,
Among at least one set of surfaces facing each other when laminating adjacent non-woven fabrics, the lump of resin is distributed on the surface of one non-woven fabric, and the lump of resin is distributed on the surface of the other non-woven fabric. A component of the ventilation duct which is not made to be . Ventilation duct comprising the components described in claim 1. In addition to including a nonwoven fabric containing thermoplastic resin fibers, the nonwoven fabric is a constituent member of a ventilation duct formed by pressing, and at least one surface of the nonwoven fabric has undergone a process of selectively heating the surface. Ventilation duct structure in which the lump of resin formed by melting the thermoplastic resin fibers on the surface is distributed in a granular form, and the surface of the nonwoven fabric on which the lump is distributed is exposed on the surface of the ventilation duct component A method for manufacturing a member, comprising:
A first step of selectively heating the surface of the nonwoven fabric containing the thermoplastic resin fibers to melt the thermoplastic resin fibers on the nonwoven fabric surface to form and distribute a lump of resin on the nonwoven fabric surface;
The non-woven fabric obtained in the first step is a single layer or laminated with another non-woven fabric, and the mold is opened so that the surface of the non-woven fabric on which the resin mass is distributed faces at least one of the press dies. A second step of feeding into the mold,
A third step of closing and pressurizing the press mold to shape the nonwoven fabric;
The manufacturing method of the ventilation duct structural member containing this. In the second step, a plurality of non-woven fabrics are stacked and supplied to the press mold,
In at least one set of mutually opposing surfaces of the nonwoven fabrics laminated adjacent to each other, the lump of resin is distributed on one nonwoven fabric surface, and the lump of resin is distributed on the other nonwoven fabric surface. 4. The method for producing a ventilation duct component according to claim 3 , wherein the nonwoven fabric is laminated so as not to be.