JP6257173B2 - Decorative materials for vehicles - Google Patents

Description

The present invention relates to a decorative member for a vehicle, in particular, comprises a practicality with design property inside the vehicle, it relates to the decorative member for that can increase the commercial value vehicle.

Decorative parts for vehicles such as decorative parts used for linings for vehicles are already known, and some of them function as decorative lighting when the passenger compartment becomes dark, such as at night.
For example, a courtesy lamp attached to the vehicle compartment side of a vehicle door is known as an example of a vehicle decorative part having such an illumination function.
The courtesy lamp is generally turned on when the door is opened, illuminates the occupant's feet, supports getting on and off, and informs the vehicle and people behind that the door is open.
Such luminescent decorative members are currently placed in various places in the passenger compartment, such as door pockets, pillars, door speakers, and cup holders, and are expected to be in high demand worldwide. Yes.
Under such circumstances, advanced decorations that are visible through light transmitted from metal are attracting attention.
As described above, when a component having a metallic feeling is visually formed by transmitting light through a metal, a metal sheet is used, and illumination light is irradiated to the vehicle interior side through the metal sheet. To do.
Such a metal sheet is disposed in a resin part which is a base material of the interior member, but the configuration of the metal sheet and the method of manufacturing the interior member by disposing the metal sheet on the base material are as follows: Various things have been proposed (see, for example, Patent Document 1).

For example, Patent Document 1 discloses a technique relating to a resin-made metal harmonized decorative part for a vehicle.
This sheet is a laminated film that functions as a transfer foil. From the side close to the surface of the resin layer serving as a substrate, an adhesive layer, an anchor layer, a metal vapor deposition layer for expressing a metallic tone, an anchor layer, a colored layer, a hard layer A coat layer and a base film having a surface subjected to hairline processing are laminated to form a single body.
Then, by in-mold molding of this sheet, a process is disclosed in which a pattern is transferred onto the surface of the resin layer serving as a base material, and after the in-mold molding, the base film is peeled off to finish the surface of the molded product in a metallic tone. ing.

JP-A-11-32478

On the other hand, in recent vehicle interior materials, the shape tends to be complicated in order to improve the design.
In particular, there are many members using curves and curved surfaces from the viewpoint of design. The members having these curves and curved surfaces give a psychologically calm impression.
However, when a sheet (film) described in Patent Document 1 that has been used in the past is used and the sheet is arranged on such a curved or curved surface, there is a problem that a tension difference occurs when the shape becomes complicated. It was happening.
This is particularly noticeable in the tension difference between the flat surface portion and the curved surface portion.
When the tension difference is generated as described above, cracks are generated in the high tension portion, that is, the curved surface portion, which may affect the design.
On the other hand, using such a sheet (film), it is conventionally performed to irradiate the sheet (film) from a light emitting source built therein and to create a decorative member having a light emitting property as described above. ing.
However, in such a sheet (film) according to Patent Document 1, since each layer is uniformly laminated and formed in a multilayer, the decorativeness becomes monotonous.
In addition, if there is a pinhole or the like at the time of printing, there is a possibility that the design property is affected.
Furthermore, there is a problem of balancing the transmission of light from the light emitting source and the visibility of the inner boundary portion, etc., ensuring higher designability and improving the commercial value.
Furthermore, there is an urgent need for a technique capable of simultaneously improving durability while ensuring higher designability.

The present invention has been made in view of the above problems, its object is to solve the cracks due to tension difference of the film, to ensure higher design quality, decorative member for a vehicle in which the commercial value was further improved Is to provide.
Another object of the present invention, it is possible to solve a problem like during printing, it is to provide a vehicle decorative member which may be in conjunction with durability also improves the design.

According to the vehicle decorative member of the present invention, the subject is a vehicle decorative component that is installed in a vehicle and has a light emitting region that emits light, and the vehicle decorative component has light transmittance. A resin base material configured to include a curved surface portion, a decorative film covered on one surface of the resin base material, and an irradiation body that emits light toward the resin base material and the resin base material. The decorative film includes a non-transmission part that shields light from the irradiation body, a transmission light adjustment layer that includes a transmission part that transmits light from the irradiation body, and the transmission film. A decorative layer that is laminated on the vehicle interior side of the vehicle , and the decorative film is a maximum that can follow the curved surface portion of the curved surface portion of the resin base material. The irradiation body is adjusted and pasted so as to have a limited tensile development rate, and the irradiation body is a plate-shaped light guide. And a long case-shaped light guide holding part for holding the light guide, and a portion located on the opposite side of the resin base material from the side covered with the decorative film The light guide holding part that holds the light guide is assembled, and the resin base material to which the light guide holding part is fixed is formed along the outer shape of the vehicle decorative component. The problem is solved by being fixed in a state of being fitted into the housing case from the opening of the housing case made of a frame.
Further, in the above-described vehicle decorative member, the decoration layer is configured to have a metal vapor deposition layer, and the maximum tensile development rate that can follow the curved surface portion is the metal in the curved surface portion. It is preferable that the tensile development rate is such that no cracks or cracks occur in the deposited layer.

Further, as a method for producing a vehicle dual decorative member, and the resin base material configured with a curved surface portion having a light transmitting property, a decorative film which is Kutsugae設on one surface of the resin substrate, the resin base And an irradiation body that irradiates light in the direction of the resin base material, and a manufacturing method of a vehicle decorative member having a light emitting region that emits light, wherein the decorative film has a thickness direction 2, the transfer layer to be thermally transferred and the release layer to be peeled are laminated, and in the plane direction, a light shielding portion that shields light from the irradiation body and the light from the irradiation body are transmitted. A transparent part is formed side by side, and a film setting step for arranging the decorative film at a fixed position with respect to the first mold, a heating softening step for applying heat to the decorative film, and the decoration Vacuum the film toward the inner wall of the first mold A vacuum forming step to follow the inner wall shape of the first mold, a second mold is placed in the first mold, the mold is closed, a softening resin is injected into the formed cavity, and the decorative film is Performing the injection molding process for in-molding and curing, and the mold release process for removing the release layer by releasing the vehicle decorative member covered with the transfer layer, and the film setting process Then, the transmission portion is set at a predetermined position, and in the vacuum forming step, the decorative film can follow the curved surface portion in the portion where the curved surface portion of the first mold is formed. A method for manufacturing a decorative member for a vehicle, which is adjusted to have a maximum tensile development rate, is also conceivable.

In the present application configured as described above, the decorative film is adjusted to have a maximum tensile development rate that can follow the curved surface portion in the curved surface portion of the resin base material.
The resin base material is often configured to have a curved surface from the viewpoint of design.
In this case, if the tensile development rate of the decorative film is increased, there arises a problem that the decorative layer is damaged.
For this reason, in the curved surface portion of the resin base material, the maximum tensile development rate that can follow this is adjusted, so that the occurrence of damage is prevented, and the vehicle decorative member having higher design properties is provided. Can be provided.
Further, when the decoration layer is a metal vapor deposition layer, a crack is generated when the tensile force is increased, and the crack is generated when this level of progress is advanced.
However, according to this invention, the crack of a metal vapor deposition layer can be prevented effectively and the decorative member for vehicles with higher designability can be provided.

More specifically, the metal deposition layer is made of aluminum, and the minimum tensile development rate that can follow the curved surface portion is effectively damaged (cracks) when it is 10% or less. Can be prevented.
In consideration of safety, it is more preferable that the tensile development rate is 6% or less.
Further, the metal vapor deposition layer can be composed of tin (Sn) or indium (In).
In this case, if the tensile development rate is 50% or less in the case of tin and 130% or less in the case of indium, cracking can be effectively prevented.

Moreover, in the above vehicle decorative member, it is preferable that the transmitted light adjustment layer has a multilayer structure.
The transmitted light adjustment layer is colored by printing, but at this time, defects such as pinholes may occur.
However, by making the transmitted light adjusting layer a multi-layer structure, the pinhole can be effectively blocked and the design is improved.
The number of layers may be two or more, and may be appropriately selected from the balance of film thickness and the like.

Further, in the above-described vehicle decorative member, gradation processing is performed at the boundary portion between the non-transmissive portion and the transmissive portion so that the color density decreases in the non-transmissive portion as it approaches the boundary portion. It is preferable that
At this time, as a specific application, the gradation process may be performed only on a proximity portion close to the boundary portion.
If comprised in this way, light emission of the boundary line of the area | region where a non-transmissive part exists, and the area | region with a transmissive part can be produced as a gentle and gentle light emission.
Therefore, the designability is further improved.

In the above vehicle decorative member, it is preferable that the resin base material is molded by mixing a black pigment.
When the decorative film has a large film thickness, the film thickness varies depending on the portion due to the difference in the added tensile force caused by the curved surface portion of the resin base material, which induces uneven light emission.
For this reason, although it is preferable to make the film thickness of a decoration film small, since the color of a resin base material can be visually recognized from the permeation | transmission part of a transmitted light adjustment layer, when the film thickness of a decoration film is thin, the transmitted light adjustment layer of There is a possibility that a boundary portion between the transmissive portion and the non-transmissive portion is visible through the surface of the vehicle decorative member.
Therefore, even if the decorative film is thinned, a black pigment is mixed into the resin base material so that the boundary between the transmission part and the non-transmission part of the transmission light adjustment layer is not visually recognized. The color is similar to
Since it comprised in this way, while thinning a decoration film and preventing light emission nonuniformity, it can prevent effectively that the boundary part of the permeation | transmission part of a transmitted light adjustment layer and a non-transmission part sees through, and is visually recognized. .

Further, in the above-described vehicle decorative member, a diffusing agent is kneaded in the resin base material, and it is preferable that the diffusing agent is an acrylic diffusing agent because adhesion is improved.
Although it is possible to use a silicon-based diffusing agent as the diffusing agent, an acrylic diffusing agent is more advantageous in terms of adhesiveness.

In the above vehicle decoration member, it is preferable that a diffusion texture is formed on the back surface of the resin base material.
From the viewpoint of luminescent properties, a diffusing agent is kneaded into the resin base material. If the amount of the diffusing agent to be kneaded is large, the adhesion of the decorative film may be lowered.
For this reason, in the present invention, diffusion wrinkles are formed on the back surface of the resin base material.
That is, in order to ensure high adhesion of the decorative film, the kneading amount of the diffusing agent is decreased, and diffusion wrinkles are formed on the back surface of the resin base material to compensate for the decrease.
Since it comprised in this way, the adhesiveness of the decorating film to a resin base material improves.

Moreover, in said vehicle decoration member, the said decoration layer has a metal vapor deposition layer, and when the half mirror effect is exhibited, it is suitable.
If comprised in this way, in the bright environment (for example, daytime) and the dark environment (for example, night), the design of the decoration member for vehicles can be visually recognized differently, and the design property is improved. .

In the method for manufacturing a vehicle decorative member, specifically, the decoration layer is configured to have a metal vapor deposition layer made of aluminum, and can follow the curved surface portion as much as possible. It is preferable that the tensile development rate is set to 10% or less, which is a tensile development rate that does not cause cracks or cracks in the metal deposition layer in the curved surface portion.
More preferably, the tensile development rate is adjusted to 6% or less.

Furthermore, in the method for manufacturing a decorative member for a vehicle described above, a top coat layer is formed on the outermost surface of the decorative film transferred to the decorative member for a vehicle by irradiation with ultraviolet rays following the mold release process. It is preferable that the ultraviolet irradiation process is further performed.
When comprised in this way, durability of the transferred decoration film can be improved.

According to the vehicle decoration member of Claim 1 thru | or 3, the crack of a metal vapor deposition layer can be prevented effectively, and the vehicle decoration member with higher designability can be provided.
According to the decorative member for a vehicle according to the fourth aspect, by making the transmitted light adjusting layer a multilayer structure, the pinhole can be effectively blocked and the design property is improved.
According to the vehicle decorative member of claim 5 and claim 6, it is possible to produce the light emission of the boundary line between the region where the non-transmissive portion exists and the region where the transmissive portion is present as a gentle and gentle light emission, Therefore, the designability is further improved.
According to the vehicle decorative member of claim 7, the decorative film can be thinned to prevent uneven light emission, and the boundary portion between the transmission portion and the non-transmission portion of the transmitted light adjustment layer is seen through. Can be effectively prevented.
According to the vehicle decorative member of claim 8, the adhesion of the decorative film to the resin base material can be further enhanced.
According to the vehicle decorative member of claim 9, the adhering property of the decorative film to the resin base material can be improved by reducing the kneading amount of the diffusing agent to the resin base material while maintaining the design property. it can.
According to the vehicle decorative member of claim 10, the half mirror effect is imparted so that the design of the vehicle decorative member differs in a bright environment (for example, daytime) and a dark environment (for example, at night). Can be directed. Therefore, the designability is improved .

It is a figure which shows the door lining for vehicles using the decorative component for vehicles which concerns on one Embodiment of this invention. It is an enlarged view of the decorative part for vehicles concerning one embodiment of the present invention. It is a disassembled perspective view of the decorative component for vehicles which concerns on one Embodiment of this invention. It is a perspective view of the storage case which concerns on one Embodiment of this invention. It is a perspective view which shows the back side of the decorative component for vehicles which concerns on one Embodiment of this invention. It is sectional drawing which shows the attachment structure of the decorative component for vehicles which concerns on one Embodiment of this invention. It is a front view of the light source unit which concerns on one Embodiment of this invention. It is a figure which shows the state by which the light guide was hold | maintained at the light guide holding part of the holder which concerns on one Embodiment of this invention. It is a figure which shows the state by which the lamp | ramp was hold | maintained at the lamp | ramp holding | maintenance part of the holder which concerns on one Embodiment of this invention. It is a perspective conceptual diagram which shows the layer structure of the decorating film which concerns on one Embodiment of this invention. It is a conceptual diagram explaining the layer structure of the cross section of the decorating film which concerns on one Embodiment of this invention. It is explanatory drawing which shows the gradation of the light shielding layer which concerns on one Embodiment of this invention. It is explanatory drawing which shows the manufacturing method of the decorating member for vehicles which concerns on one Embodiment of this invention. It is explanatory drawing which shows the manufacturing method of the decorating member for vehicles which concerns on one Embodiment of this invention. It is a sample location specific figure of the expansion | deployment experiment of the decorating film which concerns on one Embodiment of this invention. It is evaluation method explanatory drawing of the decoration film expansion | deployment experiment which concerns on one Embodiment of this invention. It is explanatory drawing which shows the half mirror effect of the decorating film which concerns on one Embodiment of this invention.

Hereinafter, a decorative member for a vehicle according to an embodiment of the present invention (hereinafter referred to as the present embodiment) will be described with reference to the drawings.
In addition, embodiment described below is only the illustration which showed application of this invention, and does not limit this invention.
That is, the shape, dimensions, arrangement, and the like of the members described below can be changed and improved without departing from the spirit of the present invention, and the present invention naturally includes equivalents thereof.

  FIG. 1 to FIG. 17 show an embodiment of the present invention. FIG. 1 is a diagram showing a vehicle door lining using a vehicle decorative component, and FIG. 2 is a vehicle decorative component portion. FIG. 3 is an exploded perspective view of the vehicle decorative component, FIG. 4 is a perspective view of the housing case, FIG. 5 is a perspective view showing the back side of the vehicle decorative component, and FIG. 6 is an attachment of the vehicle decorative component. FIG. 7 is a front view of the light source unit, FIG. 8 is a diagram showing a state in which the light guide is held by the light guide holding part of the holder, and FIG. 9 is a lamp held by the lamp holding part of the holder. FIG. 10 is a perspective conceptual diagram illustrating the layer configuration of the decorative film, FIG. 11 is a conceptual diagram illustrating the layer configuration of the cross section of the decorative film, and FIG. 12 is an explanatory diagram illustrating the gradation of the light shielding layer, FIGS. 13 and 14 are explanatory views showing a method for manufacturing a vehicle decorative member, and FIG. 15 is a development of a film. Sample site identification view of experience, 16 Evaluation illustration of film development experiments, FIG. 17 is an explanatory diagram showing a half mirror effect of the decoration film.

<< Vehicle decorative parts according to one embodiment of the present invention >>
In the following description, the front-rear direction of the vehicle means the front-rear direction during normal travel, and the inner side of the vehicle (hereinafter also simply referred to as the inner side) means the vehicle interior side (vehicle interior side). This means that the outside of the vehicle (hereinafter also simply referred to as the outside) means the outside of the vehicle. Furthermore, in the following description, the upper side (lower side) means the upper side (lower side) in a state assembled to the vehicle body.

Hereinafter, as an example of a vehicle decorative component according to the present embodiment, the use and configuration of a door lining, that is, an interior component used for the vehicle door lining R (hereinafter referred to as a light emitting ornament 41) will be described.
In describing the light-emitting ornament 41, first, the overall configuration of the vehicle door lining R including the light-emitting ornament 41 will be outlined with reference to FIG.

<Overall configuration of vehicle door lining R>
The vehicle door lining R decorates the inside of the vehicle door and is composed of a group of parts attached to a door inner panel (not shown). As components constituting the vehicle door lining R, as shown in FIG. 1, there are a pocket trim 2, a door armrest 3, and the like in addition to a light emitting ornament 41, which are attached to the inside of the door base.

  The door base is a portion that covers the inner surface of the door inner panel and forms a decorative surface of the vehicle door lining R. The door base according to the present embodiment is configured by combining an upper base and a lower base in the vertical direction, and a light emitting ornament 41, a pocket trim 2, and a door armrest 3 are attached to the inner side surface of the lower base 4. Here, the lower base corresponds to an example of a base member and is composed of a hard resin plate in the present embodiment, but the material thereof is not limited to resin, and may be made of metal, for example.

  In the vehicle door lining R, a storage space is formed between the door inner panel and the lower base, and the storage space stores a side collision pad, a speaker, or the like that absorbs an impact when a side collision (not shown) occurs. It has been. Here, the side collision pads are arranged in a range indicated by a symbol M1 in FIG. 1, and the speakers are arranged in a range indicated by a symbol M2 in FIG.

  In addition, a switch panel that is operated to adjust the opening / closing of the window is provided on the upper surface of the end portion of the door armrest 3 (the range indicated by the symbol M3 in FIG. 1). Furthermore, between the lower base and the front end portion of the door armrest 3 (a range indicated by a symbol M4 in FIG. 1), a cavity (pull pocket) in which the occupant puts his / her hand to open and close the door is formed. .

<Outline of Luminous Ornament 41>
As shown in FIG. 2, the light-emitting ornament 41 according to the present embodiment is a door lining component for a vehicle door and functions as a lighting device.
This light-emitting ornament 41 corresponds to a vehicle decoration member.
On the other hand, the light emitting ornament 41 is attached to a housing case 43 provided in the door lining body 42 as shown in FIG.
The door lining body 42 is a portion of the vehicle door lining R excluding the light emitting ornament 41.

More specifically, the housing case 43 is a frame formed along the outer shape of the light-emitting ornament 41, and as shown in FIG. 4, the vehicle interior side is open, and the bottom is on the opposite side of the opening. It has a wall 43a.
The light emitting ornament 41 is attached to the door lining body 42 by being fitted into the housing case 43 from the opening.
In addition, in order to fix the light emitting ornament 41 in a state of being fitted in the housing case 43, a plurality of holes are formed in the bottom wall 43a of the housing case 43 as shown in FIG. Then, as shown in FIG. 5, a screw 44 is inserted into the hole, or a protruding claw 45 formed protruding from the back surface of the light emitting ornament 41 (more specifically, a holder 63 to be described later) is fitted into the hole. The light emitting ornament 41 is fixed to the housing case 43 by, for example, combining them.

  The light emission ornament 41 will be described in detail. The light emission ornament 41 is a module configured by combining an ornament unit 50 and a light source unit 60 as an illuminator as shown in FIG.

The ornament unit 50 includes an ornament base material 150 and a decorative film 151, and includes a light-emitting area 50a that emits light and a non-light-emitting area 50b that does not emit light, as shown in FIG.
The ornament base material 150 corresponds to a “resin base material” in the claims.
Then, in a state where the light emitting ornament 41 is assembled, the ornament unit 50 is located in front of the light source unit 60.
More specifically, the ornament unit 50 is assembled close to the holder 63 from the front of the holder 63 described later. Here, the front of the holder 63 means the front side when viewed from the light exit surface 62 a included in the light guide 62 in a state where the light guide 62 is assembled to the holder 63.
In addition, as a method of assembling the ornament unit 50 to the holder 63, a known method can be used. However, a snap-fit method, an uneven fitting method, or the like is suitable for assembling the ornament unit 50 from the front of the holder 63.

  Further, when the light emitting ornament 41 is attached to the door lining body 42, as shown in FIG. 6, the outer edge portion of the ornament unit 50 is the door lining body 42, more specifically, the flange portion of the opening formed in the housing case 43. To join.

As shown in FIG. 7, the light source unit 60 includes an LED lamp (hereinafter simply referred to as a lamp) 61 as a light source, a light guide 62 having an emission surface 62 a that emits light from the lamp 61, the lamp 61, and a light guide. And a holder 63 for holding the light body 62.
Similarly, as shown in FIG. 7, the light guide 62 according to the present embodiment is constituted by a light guide plate that is long in a predetermined direction.

In the light source unit 60, the lamp 61 and the light guide 62 are arranged at positions adjacent to each other.
More specifically, the holder 63 is formed with the elongate case-shaped light guide holding portion 64 shown in FIG. 9 is formed.
When the light guide 62 is assembled to the light guide holder 64 and the lamp 61 is assembled to the lamp holder 65, the lamp 61 is arranged at a position adjacent to one end in the longitudinal direction of the light guide 62. become. When the lamp 61 is lit in such a state, light from the lamp 61 is incident on one end in the longitudinal direction of the light guide 62 and diffuses in the light guide 62 toward the other end in the longitudinal direction of the light guide 62. proceed. As a result, light is emitted from the emission surface 62a of the light guide 62 toward the front of the emission surface 62a.

As shown in FIG. 3, the light guide 62 is brought close to the holder 63 from the front of the holder 63 and assembled to the light guide holder 64. Here, the front of the holder 63 means the near side in a direction penetrating the paper surface in FIG.
Further, as shown in FIG. 7, the lamp 61 is assembled to the lamp holder 65 by approaching the holder 63 from the side of the holder 63, more specifically, from the side of the lamp holder 65.

As shown in FIG. 3, the components thus configured are assembled so as to be sequentially stacked.
As described above, the ornament unit 50 includes the light emitting area 50a and the non-light emitting area 50b.
Each of the light-emitting area 50 a and the non-light-emitting area 50 b includes an ornament base material 150 that is a base material made of a resin material, and a decorative film 151 disposed on the ornament base material 150.
That is, both the light-emitting area 50 a and the non-light-emitting area 50 b have a layer structure, and the decoration film 151 is attached to the surface of the ornament base material 150.
Next, the ornament base material 150, the decorative film 151, and the manufacturing method will be described.

<About the decorative film 151>
The decorative film 151 is formed in-mold with respect to the ornament base material 150, and the pattern and texture are thermally transferred.
Conceptually, as shown in FIG. 10, at least a light shielding layer 151b, a metal vapor deposition layer 151d, a hairline pattern layer 151f / tint layer 151e, and a topcoat layer 151g are laminated with an anchor layer 151c sandwiched as appropriate. It is transferred to the ornament base material 150 in a state.

The detailed structure of the decorative film 151 before in-mold processing is shown in FIG.
As shown in FIG. 11, the decorative film 151 is largely composed of a transfer layer 151A and a release layer 151B.
The transfer layer 151A is configured by laminating an adhesive layer 151a, a light shielding layer 151b, a metal vapor deposition layer 151d, a pattern / coloring layer 151c, and a topcoat layer 151g from the side close to the ornament base material 150.
In the present embodiment, the handle / colored layer 151c has a two-layer structure in which a tint colored layer 151e and a hairline handle layer 151f are stacked.
However, the pattern / colored layer 151c is not necessarily required and can be omitted.
The release layer 151B is made of a release film and is peeled off after the transfer layer 151A is transferred.
The light shielding layer 151 b corresponds to a “transmitted light adjusting layer” in the claims.

In the present embodiment, the thickness of the decorative film 151 is set to about 25 to 370 μm, and an example of a transfer layer 151A of about 5 to 70 μm and a release layer 151B of about 20 to 300 μm is shown ( The actual measured value of a specific example product is as shown in FIG.
In addition, FIG. 11 is a conceptual diagram for explaining the laminated structure, and the ratio of the layer thickness in this figure does not match the actual layer thickness value.

In the present embodiment, an aluminum film is used as the metal vapor deposition layer 151d.
Moreover, as the hairline pattern layer 151f, the fineness of the hairline is set to 0.2 mm. This is the minimum level of current gravure printing, but a thinner setting may be used if possible in the technology.
In the present embodiment, a standard satin silver color is selected for the tint colored layer 151e, and thereby the texture of the metal vapor deposition layer 151d can be further utilized.

Note that after the in-mold molding, the transfer layer 151A is transferred and remains on the surface of the ornament base material 150, and the release layer 151B is removed.
Therefore, in the finished product, the top coat layer 151g is disposed on the outermost surface.

The light shielding layer 151b has a two-layer structure.
This is to prevent pinhole defects during printing of the light shielding layer.
And the notch K1 is formed in this light shielding layer 151b.
The notch K1 is formed in an arbitrary shape that emits light to a portion where light emission is desired.
That is, the light shielding layer 151b does not transmit the light from the light emitting unit 60 in places other than the notch K1 (hereinafter referred to as “light shielding part K2”), and only the part of the notch K1 from the light source unit 60. Of light.
The cutout portion K1 serves as the light-emitting region 50a. Therefore, the light emitting body that emits light in the shape of the cutout portion K1 can be visually recognized from the vehicle interior.
The cutout portion K1 corresponds to the “transmission portion” in the claims, and the light-shielding portion K2 other than the cutout portion K1 in the light-shielding layer is the “non-transmission portion” in the claims. Part.

At this time, the gradation printing process is applied to the boundary portion between the cutout portion K1 and the light shielding portion K2.
That is, as shown in FIG. 12, in the present embodiment, the black color gradually becomes thinner toward the cutout portion K1 in the 5 mm width portion from the boundary portion (edge portion) between the cutout portion K1 and the light shielding portion K2. The gradation printing process is performed so that the black gravure ink gradually disappears (ie, gradually becomes light gray).
For this reason, it becomes possible to produce a faint and soft lighting effect, and the design properties (especially the design properties during light emission) are improved.

Further, in the present embodiment, the ornament base material 150 is mixed with a black pigment.
As will be described later, this is an improvement accompanying thinning of the decorative film 151.
In the state molded as a product, the film thickness of the decorative film 151 varies depending on the location depending on the size of the diaphragm generated by the product shape (that is, the magnitude of tension).
That is, the film tension is larger near the vertex of the curved surface shape than the portion near the flat, and therefore the film thickness near the vertex of the curved surface shape is thinner than the portion near the flat shape.
Due to such a phenomenon, when the film thickness is large, light emission unevenness may be induced.

For this reason, in this embodiment, it was decided to reduce the film thickness of the decorative film 151, but when the film thickness is small, this time, the boundary part between the notch K1 and the light shielding part K2 is transparent. There is a possibility of being visually recognized.
Therefore, in this embodiment, the black pigment is mixed with the ornament base material 150 to approximate the color difference between the ornament base material 150 and the light shielding layer 151b, so that the boundary portion between the notch K1 and the light shielding portion K2 is transparent. Is effectively prevented from being visually recognized.

Furthermore, if the amount of the diffusing agent kneaded into the ornament base material 150 is large, the adhesion of the decorative film 151 may be lowered. Therefore, in the present embodiment, diffusion wrinkles are formed on the back surface of the ornament base material 150. Is formed.
That is, in order to ensure high adhesion of the decorative film 151, the amount of the diffusing agent kneaded is reduced, and as a compensation for the reduction, diffusion wrinkles are formed on the back surface of the ornament base material 150.
Since it comprised in this way, the adhesiveness of the decorating film 151 to the ornament base material 150 improves.
The diffusion texture may be formed by any method, but may be formed by, for example, etching into a mold or sand blasting.
Any diffusing agent may be used, but an acrylic diffusing agent is preferably used.
That is, although a silicon type diffusing agent can be used, the use of an acrylic type diffusing agent provides better adhesion.

<Method for Manufacturing Light Emitting Ornament 41>
Next, a method for manufacturing the light-emitting ornament 41 according to the present embodiment will be schematically described with reference to FIG.
First, as shown to Fig.13 (a), a decorating film heating process is performed.
In this process, the film setting process for fixing the decorative film 151 to the clamp T2 disposed in the first mold T1, and the softening by heating and softening the decorative film 151 using the hot pack T3. The steps are executed in order.

Next, as shown in FIG. 13B, a vacuum forming process is performed.
In this step, vacuum suction is performed, and the interior of the mold is evacuated to cause the decorative film 151 to follow the inner wall shape of the first mold T1.
Next, an injection molding process is performed as shown in FIG.
In this step, the second mold T4 is moved to the first mold T1 side to close the mold, and the softened resin is filled in the cavity and then cured. In this example, a so-called hot runner format is adopted.

Next, as shown in FIG. 13 (d), a mold release process is performed to release the molded product, and the release layer 151B is released.
In this example, the first mold T1 is a fixed mold and the second mold T4 is a movable mold.
In this example, an ultraviolet irradiator U is provided, and an ultraviolet irradiation process is performed.
In this step, the surface of the transfer layer 151A that has been transferred is irradiated with ultraviolet rays to form a topcoat layer 151g.

It is also possible to use a method as shown in FIG.
In the example shown in FIG. 14, the fixed type and the movable type are opposite to the example of FIG.
That is, the first mold T1 is a movable mold, and the second mold T4 is a fixed mold.

In this example, a feeding / winding device T5 for the decorative film 151 is disposed on the first mold T1 side.
The feeding / winding device T5 includes rollers T6 and T6 that are arranged one by one at positions where the first mold T1 is sandwiched vertically, and a detection sensor T7.
The rollers T6 and T6 respectively hold the release layers 151B at both ends of the decorative film 151, and the decorative film 151 is passed to the opening side of the first mold T2.

And the predetermined position (position where a pattern is arrange | positioned in the correct position) is detected with the detection sensor T7, and it stops, and the decoration film 151 is fixed by clamp T2 in this state. This process is a film setting process.
Next, as in the above example, heat is applied (the hot pack T3 is not necessarily required and any heating method may be used), the decorative film 151 is softened, and vacuum suction is applied. The decorative film 151 is made to follow the inner wall shape of the first mold T1.

Next, the first mold T1 is moved to the second mold T2 side to close the mold, and the softened resin is filled in the gap and then cured. In this example, a so-called hot runner format is adopted. This process is an injection molding process.
Then, when the mold is released and the first mold T1 is returned to the original position together with the feeding / winding device T5, the release layer 151B moves following, so that the release layer 151A peels off from the transfer layer 151A. The layer 151A is transferred to the surface of the ornament substrate 150 and remains. This process is a mold release process.
And the decoration film 151 will be sent between roller T6, T6 for the next shaping | molding.

In addition, the ultraviolet irradiation process by the ultraviolet irradiation machine U is performed similarly to the said example.
In this step, the surface of the transfer layer 151A that has been transferred is irradiated with ultraviolet rays to form a topcoat layer 151g.

<Verification of thinning of decorative film 151>
Subsequently, it verifies about thinning of a decoration film.
In particular, the metal vapor deposition layer 151d that is significantly affected by the stretching tension is verified.
In the present embodiment, as described above, the verification is performed when an aluminum film is used as the metal vapor deposition layer 151d.
Table 1 shows a comparison table between the development rate (corresponding to “tensile development rate”) of the metal vapor deposition layer 151d and the appearance state.

As described above, when the development rate exceeds 60%, a crack occurs in the metal deposition layer 151d. When the development rate is in the range of more than 10% and up to 60%, the crack does not occur, but a crack occurs.
It was also found that when the expansion rate exceeds 10%, whitening occurs.
As a result, if the development rate exceeds 10%, micro cracks are generated, which is not preferable in terms of appearance quality. Therefore, it is verified that it is preferable to set the development rate to 10% or less, preferably 6% or less for safety. did it.

Next, the arrangement of the decorative film 151 was verified using the actual light emitting ornament 41 as a sample.
This analysis was performed using “resin / composite molding analysis software” which is generally used.
Enter the cavity surface shape of the mold and the physical properties of the decorative film 151, simulate the appearance of the decorative film 151 vacuumed in the mold, and how the thickness of the decorative film 151 changes. It was confirmed numerically.

Next, the correlation between the development rate prediction result by the above simulation (hereinafter simply referred to as “CAE result”) and the actual development rate was verified.
The area where the development rate is measured is shown in FIG.
As shown in FIG. 15, the development rate is measured by dividing into 6 regions.
A specific example of the actual measurement method of the molded product is shown in FIG.
In this measurement method, a 1 mm square film is used, and after molding, the area of the stretched square is measured to calculate how many percent of the undeveloped state is developed.
The results are shown in Table 2.

Thus, in all the light-emitting ornaments 41 according to the present embodiment, the development rate was kept at 6% or less, and it was verified that cracks could not occur within this 6% or less range.
Thus, such a simulation result can be applied to the ornament base material 151 and reflected in the design.
That is, in designing the ornament base material, it is possible to predict whether or not the deeply drawn shape can be transferred without cracks in the decorative film 151.

In other words, the present simulation can be performed to identify locations where the development rate exceeds 6%, and the design can be changed in advance.
And after confirming that a crack does not generate | occur | produce as a result of simulation, it can transfer to an actual shaping | molding stage.

  Further, in the correlation with the actual development rate, although there was a slight difference in the absolute value, it was within the error range, which was consistent with the CAE result, and it was verified that there was no problem in appearance quality.

In the present embodiment, an aluminum film is used as the metal vapor deposition layer 151d. However, the present invention is not limited to this and can be appropriately selected. In particular, a tin (Sn) film and an indium (In) film are preferably used.
When these tin and indium are used, cracks do not occur at the tensile development rate exceeding the limit, and cracks occur.
When the metal vapor deposition layer 151d is a tin film, the tensile development rate is 50% or less, and when the metal vapor deposition layer 151d is an indium film, it can be avoided that the tensile development rate is 130% or less. .

<About the half mirror effect>
Next, the half mirror effect of the decorative film 151 will be described with reference to FIG.
FIG. 17B is a cross-sectional explanatory view taken along line AA in FIG.
As shown in FIG. 17, the metal vapor deposition layer 151d provides a half mirror effect.
In other words, this is an effect imparted by a thin metal film having a thickness of about 0.01 to 0.1 μm. In a situation where the interior of the vehicle is bright, light from the surroundings is reflected. In a situation where the texture (that is, the metallic pattern) is visually recognized and the vehicle interior is dark, the light from the light source unit 60 is transmitted and visually recognized as surface-emitting illumination.
Thus, in this embodiment, by adopting the metal vapor deposition layer 151d, it is possible to provide a half mirror effect, and it is possible to provide a light emitting ornament 41 that has functionality and higher design properties.

R Vehicle door lining 2 Pocket trim 3 Door armrest 4 Lower base 41 Luminous ornament (vehicle decoration)
42 Door lining main body 43 Housing case 43a Bottom wall 44 Screw 45 Projection claw 50 Ornament unit 50a Light emitting area 50b Non-light emitting area 60 Light source unit 61 Lamp 62 Light guide 62a Emission surface 63 Holder 64 Light guide holder 65 Lamp holder 150 ornament base material (resin base material)
151 Decorative film 151A Transfer layer K1 Notch (transmission part)
K2 Light-shielding part (non-transmissive part)
151a Adhesive layer 151b Light-shielding layer (transmitted light adjustment layer)
151c handle / colored layer 151d metal deposition layer 151e tint colored layer 151f hairline handle layer 151g topcoat layer 151B release layer T1 first mold T2 clamp T3 hot pack T4 second mold T5 feed take-up device T6 roller T7 detection sensor

Claims (10)

A decorative part for a vehicle that is installed in a vehicle and has a light emitting region that emits light,
The decorative part for a vehicle includes a resin base material having light transmittance and a curved surface part, a decorative film covered on one surface of the resin base material, the resin base material, and the resin An irradiating body that irradiates light toward the substrate, and
The decorative film is
A transmitted light adjusting layer having a non-transmissive portion that blocks light from the irradiating body and a transmissive portion that transmits light from the irradiating body;
A decorative layer laminated on the interior side of the vehicle of the transmitted light adjustment layer, and comprising at least
The decorative film is affixed to the curved surface portion of the resin base material so as to have a maximum tensile development rate that can follow the curved surface portion,
The irradiator has a plate-shaped light guide and a long case-shaped light guide holder that holds the light guide,
The light guide body holding part that holds the light guide body is assembled to a portion located on the side opposite to the side covered with the decorative film in the resin base material,
The resin base material to which the light guide holding portion is fixed is fitted into the housing case from an opening of the housing case formed of a frame body formed along the outer shape of the vehicle decorative component. A decorative member for a vehicle characterized by being fixed in a state. The decorative layer is configured to have a metal vapor deposition layer, and the maximum tensile development rate that can follow the curved surface portion is such that the metal vapor deposition layer does not crack or crack in the curved surface portion. The decorative member for a vehicle according to claim 1, which has a tensile expansion ratio. The metal vapor deposition layer is made of aluminum,
The vehicle decorative member according to claim 2 , wherein a minimum tensile development rate that can follow the curved surface portion is 10% or less. The vehicle decorative member according to claim 1, wherein the transmitted light adjustment layer has a multilayer structure. At the boundary between the non-transmissive part and the transmissive part,
The vehicle decorative member according to claim 1, wherein the non-transparent portion is subjected to gradation processing so that the color density becomes lighter as it approaches the boundary portion. The vehicle decoration member according to claim 5, wherein the gradation process is performed only on a proximity portion close to the boundary portion. The vehicle decorative member according to claim 1, wherein the resin base material is formed by mixing a black pigment. The resin base material is kneaded with a diffusing agent,
The vehicle decoration member according to claim 1, wherein the diffusing agent is an acrylic diffusing agent. The vehicle decorative member according to claim 1, wherein diffusion wrinkles are formed on a back surface of the resin base material. The vehicle decoration member according to claim 1, wherein the decoration layer includes a metal vapor deposition layer and exhibits a half mirror effect.

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