JP2017102016A - Vehicle interior component - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a vehicle interior component that allows an actual appearance due to a change in incidence direction or visual direction to approximate to an actual appearance of a carbon interior component.SOLUTION: An indicator dial plate 1 comprises: a base material 2; a printing layer 3; and a clear layer 4. The printing layer 3 is colored in accordance with a carbon color, in which a plurality of rectangular regions 10S and 10T where a gradation of color between bright and dark changes along a gradation change direction are formed. A first rectangular group S in which the gradation change direction is a vertical direction and the rectangular region 10S adjacent to a lateral direction is arranged so as to be deviated toward the vertical direction, and a second rectangular region group T in which the gradation change direction is the lateral direction and the rectangular region 10T adjacent to the vertical direction is arranged so as to be deviated toward the lateral direction are alternately arranged. A dense side of each rectangular region 10T is configured to oppose a dense side of each rectangular region 10S. The clear layer 4 has a plurality of convex parts 41 formed in a convex part array direction. Each convex part 41 is formed into a semi-columnar shape extending in the gradation change direction.SELECTED DRAWING: Figure 2

Description

  The present invention relates to a vehicle interior part.

  A plurality of interior parts are used in the interior of a vehicle or the like, and in recent years, carbon interior parts using carbon fibers have been used in order to improve the sense of quality. The carbon interior part is constituted by a prepreg obtained by impregnating a woven carbon fiber with a resin. By the way, carbon interior parts have been used only in some vehicles and the like because the carbon fibers themselves are expensive. Therefore, a carbon-like interior part that simulates the appearance of the carbon interior part has been proposed (see, for example, Patent Document 1). The carbon-like interior part expresses the pattern in the carbon interior part in a pseudo manner by forming a carbon-like pattern on the base material.

JP-A-2015-99084

  By the way, interior parts differ in the incident direction of the light which injects into interior components, and the visual recognition direction where a passenger | crew visually recognizes interior components by the place of use. Therefore, the appearance of the carbon interior part also varies depending on the change of the incident direction or the viewing direction. In the above carbon-tone interior parts, the actual appearance due to the change in the incident direction and the viewing direction is not taken into consideration, and there is room for further improvement.

  An object of the present invention is to provide an interior part for a vehicle that can approximate an actual appearance of a carbon interior part due to a change in an incident direction or a viewing direction.

  In order to achieve the above object, an interior component for a vehicle according to the present invention is formed on a base material, a printed layer formed by laminating the base material, and formed with a carbon pattern, and the base material. A transparent layer that is laminated on the viewing side and has transparency, and the printing layer has a color scheme corresponding to the carbon color, and a plurality of rectangular regions in which the shade changes along the shade change direction. A first rectangular region group formed, wherein the shade change direction is the first direction, and adjacent rectangular regions in a second direction orthogonal to the first direction are shifted in the first direction; The gradation change direction is the second direction, and the second rectangular area group in which the rectangular areas adjacent in the first direction are arranged shifted in the second direction are alternately arranged, and the clear layer is The shade change method according to each rectangular area A plurality of convex portions are formed in the convex portion arrangement direction orthogonal to each other, and each of the convex portions is formed such that the length in the shade change direction is longer than the length in the convex portion arrangement direction, and at least the shade change direction. The outer shape when viewed from the above is formed in a curved line.

  Further, in the vehicle interior part, each of the rectangular regions in the first rectangular region group continuously changes in the first direction, and each of the rectangular regions in the second rectangular region group is It is preferable that the color changes continuously in the second direction and the dark side of each rectangular area of the second rectangular area group is opposed to the dark side of each rectangular area of the first rectangular area group.

  In the vehicle interior part, it is preferable that the rectangular area is a rectangle, and the direction of change in shading is a long side direction of the rectangular area.

  Further, in the vehicle interior part, the base material is permeable, the printed layer is formed on the opposite side to the viewing side with respect to the base material, and the vehicle interior part is an instrument dial. It is preferable that

  In the vehicle interior component according to the present invention, the first rectangular region group and the second rectangular region group having different shade change directions in the printed layer are alternately arranged, and the shade of each rectangular region in each rectangular region group in the clear layer. A plurality of protrusions that are long in the direction of change and at least viewed from the direction of light and shade change and whose outer shape is curved are formed in the direction of arrangement of the protrusions. The change in the incident direction of the light incident on the component can change the reflected light from the vehicle interior component that is incident on the passenger's eyes, so the actual interior looks as a result of changes in the incident direction and the viewing direction. It is an object to provide an interior part for a vehicle that can approximate the actual appearance of the part.

FIG. 1 is a diagram illustrating an interior part for a vehicle according to an embodiment. FIG. 2 is an enlarged view of a main part of the vehicle interior part according to the embodiment. FIG. 3 is a partial cross-sectional view of the vehicle interior component according to the embodiment. FIG. 4 is an enlarged view of a main part of the vehicle interior part according to the embodiment. FIG. 5 is an enlarged view of a main part of the vehicle interior part according to the embodiment. FIG. 6 is a perspective view of a main part of the vehicle interior part according to the embodiment. FIG. 7 is a partial cross-sectional view of a vehicle interior part according to a modification. FIG. 8 is a perspective view showing a convex portion of a vehicle interior part according to a modification.

  Hereinafter, an embodiment of an interior part for a vehicle according to the present invention will be described in detail based on the drawings. In addition, this invention is not limited by this embodiment. In addition, constituent elements in the following embodiments include those that can be easily assumed by those skilled in the art or those that are substantially the same. The constituent elements in the following embodiments can be variously omitted, replaced, and changed without departing from the gist of the invention.

Embodiment
First, vehicle interior parts according to the embodiment will be described. FIG. 1 is a diagram illustrating an interior part for a vehicle according to an embodiment. Here, the X direction in FIG. 1 (including FIGS. 2 to 8) is the lateral direction of the vehicle interior component in the present embodiment. The Y direction is the vertical direction of the vehicle interior part in the present embodiment, and is the direction orthogonal to the horizontal direction. The Z direction is a vertical direction of the vehicle interior part in the present embodiment, and is a direction orthogonal to the horizontal direction and the vertical direction. The X1 direction is the left direction of the vehicle interior part, and the X2 direction is the right direction of the vehicle interior part. The Y1 direction is the upward direction of the vehicle interior part, and the Y2 direction is the downward direction of the vehicle interior part. The Z1 direction is the viewing direction, and the Z2 direction is the opposite direction to the viewing direction.

  The vehicle interior component according to the present embodiment is an instrument dial 1 as shown in FIG. The dial 1 for instruments is one of the elements constituting a meter (instrument device) that is visually recognized by a passenger such as a vehicle (not shown). An instrument dial 1 as an interior part for a vehicle in the present embodiment is a dial for a speedometer, and is formed in a circular flat plate. The dial 1 for the instrument is formed with a through hole 1a into which a pointer (not shown) is inserted at the center. The dial 1 for an instrument has a plurality of character portions 1b for displaying speed in the vicinity of the outer periphery. Each character portion 1b is formed with a non-printing region corresponding to a character shape for displaying a speed or a transmissive printing region coated with a paint that transmits a wavelength in the visible light region in a printing layer 3 to be described later. That is, each character part 1b is a non-pattern formation area in which the carbon tone pattern M is not formed. In addition, each character portion 1b is formed with a flat area corresponding to a character shape for displaying a speed in a clear layer 4 to be described later. Each character portion 1b receives light emitted from a light source (not shown) arranged on the opposite side (Z2 direction side: back side) to the viewing side (Z1 direction side: front side) viewed by the occupant of the instrument dial 1. Irradiate the viewer side. Thereby, the passenger | crew can recognize the character which displays the speed of the dial 1 for instruments at night etc. In addition, the dial 1 for the instrument has a plurality of notches 1c in the circumferential direction on the outer periphery. A light guide (not shown) is disposed in each notch 1c, and for example, the light emitted from the above-described light source is irradiated to the viewing side through the light guide. In addition, the dial 1 for instrument 1 does not need to have each notch part 1c formed. In this case, it is preferable that the area | region corresponding to each notch part 1c of the dial 1 for instruments is formed so that light may permeate | transmit from the opposite side to the visual recognition side.

  The instrument dial 1 is formed of a plurality of layers. FIG. 2 is an enlarged view of a main part of the vehicle interior part according to the embodiment. FIG. 3 is a partial cross-sectional view of the vehicle interior component according to the embodiment. FIG. 4 is an enlarged view of a main part of the vehicle interior part according to the embodiment. FIG. 5 is an enlarged view of a main part of the vehicle interior part according to the embodiment. FIG. 6 is a perspective view of a main part of the vehicle interior part according to the embodiment. Here, FIG. 3 is an AA cross-sectional view of FIG. 4 is a view in which the clear layer is not shown, and FIGS. 3, 5 and 6 (including FIGS. 7 and 8) are illustrations in which the carbon-like pattern of the print layer is not shown. FIG. 6 shows one rectangular area in the first rectangular area group and one rectangular area in the second rectangular area group adjacent to the first rectangular area group.

  As shown in FIG. 3, the instrument dial 1 is composed of a base material 2, a printed layer 3, and a clear layer 4. The dial 1 for an instrument as an interior part for a vehicle in the present embodiment has a printed layer 3 laminated on the opposite side (Z2 direction side) to the viewing side of the base material 2 and the viewing side (Z1 direction side) of the base material 2. And the clear layer 4 is laminated.

  The base material 2 is formed by molding a synthetic resin into a desired flat plate shape (in this embodiment, a circular flat plate) using a molding die or the like. The synthetic resin which comprises the base material 2 is an acrylic resin, a polycarbonate, etc., for example, transmits the wavelength of visible region, and has transparency. In addition, the thickness (length in the Z direction) of the base material 2 is sufficiently thicker than the printing layer 3 and the clear layer 4.

  The printing layer 3 is formed by being laminated on the opposite side of the substrate 2 to the side opposite to the viewing side by attaching the synthetic resin ink to the surface on the side opposite to the viewing side of the substrate 2. . The synthetic resin constituting the printing layer 3 is, for example, an acrylic resin, polyvinyl chloride, or the like, and has a color applied to a color scheme corresponding to a carbon color described later. As shown in FIGS. 2 and 4, the printed layer 3 has a carbon pattern M formed thereon. The carbon-tone pattern M is configured by an aggregate of a plurality of rectangular areas 10S and 10T (hereinafter also simply referred to as “rectangular areas 10”) formed on the viewing side surface of the printed layer 3. Each rectangular area 10 in this embodiment is a rectangle. The pattern of the prepreg made by impregnating a carbon fiber woven into a twill weave under the carbon fiber in the other direction where the carbon fiber in one direction intersects, so the shape of the portion exposed to the visible side of the carbon fiber is It becomes a rectangle (including a substantially rectangular shape). That is, the carbon-tone pattern M can be approximated to a prepreg pattern in which a carbon fiber knitted in a twill weave is impregnated with a resin because each rectangular region 10 is rectangular. Each rectangular area 10 is formed with a color scheme corresponding to the carbon color. Here, the carbon color refers to a color that can be reproduced in a prepreg obtained by impregnating a knitted carbon fiber with a resin, and may be a color representative of a carbon color such as black or white, or an orange or blue color. Each rectangular region 10 is formed with shades 31 of a color scheme corresponding to the carbon color along the shade change direction. The light and shade 31 is formed so that the color becomes darker in the light and shade change direction. The light / dark change direction in the present embodiment is parallel to the long side direction (longitudinal direction) of each rectangular region 10. The shade 31 is formed by continuously changing. For example, when the carbon color is black, each rectangular region 10 is formed so as to continuously change so that the light side in the light / dark change direction of the light / dark 31 is a gray close to black and the dark side is black.

  Each rectangular area 10 is classified into two rectangular area groups, a first rectangular area group S and a second rectangular area group T. In the printing layer 3, the first rectangular area group S and the second rectangular area group T are alternately arranged adjacent to each other. That is, the first rectangular area groups S and the second rectangular area groups T are not adjacent to each other.

  The first rectangular area group S is composed of a plurality of rectangular areas 10S. In each rectangular region 10S, the shade change direction is the first direction, and the upward direction (Y1 direction) of the vertical direction (Y direction) in the present embodiment, and the shade change directions are all arranged in the same direction. In each rectangular region 10S, the density 31 continuously changes so as to be continuously darker in the upward direction, that is, the lower side is the lighter side and the upper side is the darker side. Further, each rectangular area 10S is shifted in the upward direction from the adjacent rectangular area 10S in the left direction (X1 direction) in the second direction orthogonal to the first direction, the horizontal direction (X direction) in the present embodiment, that is, It is arranged in steps. Each rectangular region 10S in the present embodiment is arranged such that the long side direction is the vertical direction and is shifted upward by half the length of the long side direction of the rectangular region 10S.

  The second rectangular area group T includes a plurality of rectangular areas 10T. In each rectangular region 10T, the shade change direction is the second direction, the left direction (X1 direction) of the horizontal direction (X direction) in the present embodiment, and the shade change directions are all arranged in the same direction. In each rectangular region 10T, the shading 31 continuously changes so as to continuously darken in the left direction, that is, the right side becomes the thin side and the left side becomes the dark side. Further, each rectangular area 10T is arranged such that adjacent rectangular areas 10T in the first direction, the vertical direction (Y direction) in the present embodiment, in the upward direction (Y1 direction) are shifted to the left, that is, stepped. Yes. Each rectangular region 10T in the present embodiment is arranged such that the long side direction is the horizontal direction and is shifted to the left by half the length in the long side direction of the rectangular region 10T.

  Here, each rectangular area 10S is adjacent to the left side of the rectangular area 10T of the second rectangular area group T located on the right side on the upper side of the upper side and the left side, and is on the lower side. Of the right side, the lower side is adjacent to the right side of the rectangular region 10T of the second rectangular region group T located on the left side. The upper side in each rectangular area 10S is a dark side, and the left side in each rectangular area 10T is a dark side. On the other hand, the lower side in each rectangular region 10S is a thin side, and the right side in each rectangular region 10T is a thin side. That is, the dark side of each rectangular area 10T of the second rectangular area group T faces the dark side of each rectangular area 10S of the first rectangular area group S, and the thin side of each rectangular area 10T of the second rectangular area group T is the first side. It faces the thin side of each rectangular area 10S of the rectangular area group S. Here, the term “opposite” refers to a direction in which the end of one dark side (thin side) and the other dark side (thin side) of the rectangular regions 10S and 10T intersect each other. To face each other.

  The clear layer 4 is printed by being laminated on the viewing side with respect to the substrate 2 by attaching an ink made of a synthetic resin to the viewing side surface of the substrate 2. The synthetic resin constituting the clear layer 4 is the same as the printed layer 3 and transmits the wavelength in the visible light region and has transparency. As shown in FIGS. 2 and 5, the clear layer 4 has a plurality of convex portions 41 in the convex portion arrangement direction orthogonal to the shade change direction according to each rectangular region 10, in the short side direction of the rectangular region 10 in this embodiment. Is formed. The convex portions 41 in the present embodiment have the same shape, and are formed with an interval from the convex portions 41 adjacent to each other in the convex portion arrangement direction and the shading change direction, but are adjacent to each other in at least one direction. It may be formed without an interval from the portion 41. Each convex portion 41 (eight in the present embodiment) of the clear layer 4 represents one carbon fiber in the clear layer 4 in a pseudo manner. A boundary R is formed between the adjacent convex portions 41. Each boundary R is formed in a straight line. When viewed from the viewing side, the printed layer 3 has a band shape in which the portion defined by the adjacent boundary R extends in the shading change direction, and forms a pattern corresponding to one carbon fiber in the carbon tone pattern M. . Therefore, the carbon-tone pattern M can be approximated to one carbon fiber in the prepreg. Thereby, the actual appearance can be approximated to the actual appearance of the carbon interior part, that is, the real feeling can be further increased. Here, as shown in FIG. 6, the convex portion arrangement direction of the plurality of convex portions 41 corresponding to each rectangular region 10S in the first rectangular region group S is the horizontal direction (X direction), and the second rectangular region group T The convex portion arrangement direction of the plurality of convex portions 41 corresponding to each rectangular region 10T in FIG. Each convex part 41 is formed such that the length L1 in the shading change direction is longer than the length L2 in the convex part arrangement direction. The convex portion 41 in the present embodiment has a semi-cylindrical shape that extends in the light and shade change direction. Each of the convex portions 41 has an outer shape 41a (dotted line in the figure) formed in a curved line when viewed from the direction of change in shading, and an outer shape 41b (dotted line in the drawing) viewed from the direction of arranging the convex portions is formed with a straight line. ing.

  Here, the printing layer 3 and the clear layer 4 are formed using an inkjet printer (not shown) as an example. The ink jet printer moves the mounted carriage relative to the base material 2 in the vertical direction or the horizontal direction, and the UV curable ink, which is an ink made of synthetic resin, from the carriage or the visual side surface of the base material 2 or the visual recognition. Dispense toward the opposite side. Next, the ink jet printer moves the mounted UV light source relative to the base material 2 in the vertical direction or the horizontal direction, and landed on the viewing side surface of the base material 2 or the surface opposite to the viewing side. The curable ink is cured by irradiating light with a wavelength in the ultraviolet region from an ultraviolet light source. Thereby, the inkjet printer forms the printing layer 3 on which the desired pattern, that is, the carbon-tone pattern M, is formed on the surface opposite to the viewing side of the substrate 2. In addition, the inkjet printer forms the clear layer 4 having a desired shape, that is, a plurality of convex portions 41 formed in the convex arrangement direction on the surface on the viewing side of the substrate 2. Inkjet printers are designed to land and cure the discharged UV curable ink droplets on the substrate 2, so that printing is performed on the substrate 2 to form a desired pattern and a desired shape. Even if it performs, the pattern and shape which approximated the desired thing will be formed. Further, the formation of the carbon-tone pattern M in the print layer 3 may be a print formation by a screen instead of a print formation by an ink jet printer.

  As described above, the dial 1 for an instrument according to the present embodiment has different shade change directions in the print layer 3, and the dark side of the rectangular region 10T adjacent to the dark side of the rectangular region 10S is opposed to the rectangular region 10S. Since the light side of the rectangular area 10T adjacent to the light side is opposed to each other and the carbon pattern M is configured by alternately arranging the first rectangular area group S and the second rectangular area group T, the instrument dial 1 On the other hand, for example, when light is incident from one of the light sources L1 and L2 shown in FIGS. 2, 4, and 5, the side closer to the light sources L1 and L2 is the lighter side and the far side is the darker side. It becomes. In the woven carbon fiber, both ends of the carbon fiber exposed on the viewing side in the direction of entering under the carbon fiber are lower than the central portion, and unevenness is formed. When light is incident from a light source separated in the extending direction of the woven carbon fiber (the direction in which one carbon fiber enters under the other carbon fiber), the portion exposed on the viewing side is in the extending direction of the carbon fiber. Due to the presence of the irregularities, a large amount of light is incident on one end and the center near the light source among both ends, and a small amount of light is incident on the other end far from the light source among both ends. The That is, when a portion exposed from the occupant to the viewing side is viewed, the side closer to the light source appears brighter and the far side appears darker. Therefore, the carbon-tone pattern M reproduces a portion exposed to the viewer side among the carbon fibers in which the rectangular regions 10 are woven.

  Further, the dial 1 for an instrument according to the present embodiment is long in the shading change direction of each rectangular area 10 of each rectangular area group S, T in the clear layer 4, and the outer shape 41a when viewed from at least the shading change direction is curved. Since the plurality of convex portions 41 are formed in the convex portion arrangement direction, the reflection states by the rectangular region groups S and T differ depending on the direction of light incident on the instrument dial 1. As shown in FIG. 5, for example, when light from the light source L1 is incident on the instrument dial 1, each convex portion 41 corresponding to each rectangular area 10S of the first rectangular area group S (light / dark) Light is incident from the convex arrangement direction with respect to the change direction (upward direction), and the light intensity changes with respect to the respective convex portions 41 (lightness change direction is upward) corresponding to the rectangular regions 10T of the second rectangular region group T. Light enters from the direction. Further, when light from the light source L2 is incident on the instrument dial 1, each convex portion 41 corresponding to each rectangular region 10S of the first rectangular region group S (the light and shade change direction is upward). On the other hand, light is incident from the shade change direction, and light is incident from the convex arrangement direction with respect to each convex portion 41 (the shade change direction is upward) corresponding to each rectangular region 10T of the second rectangular region group T. . Here, with respect to the convex portion 41, the light incident from the light shade changing direction is different from the light incident from the convex portion arrangement direction. When viewed from the viewing side, the light incident on the convex portion 41 from the light and shade change direction is reflected more toward the light and shade change direction that is the reflection direction than the light incident on the convex portion 41 from the convex portion arrangement direction. That is, when light is incident from the light source L1, the portion corresponding to each rectangular region 10S of the first rectangular region group S in the carbon-tone pattern M looks bright, and the occupant has visibility of the light and shade 31 of this portion. Since this is improved, the shade 31 can be clearly recognized, and the portion corresponding to each rectangular region 10T of the second rectangular region group T looks dark, and the visibility of the shade 31 of this portion by the occupant decreases, so the shade 31 is It cannot be clearly recognized. In addition, when light is incident from the light source L2, the portion corresponding to each rectangular region 10S of the first rectangular region group S in the carbon-tone pattern M looks dark, and the visibility of the light and shade 31 of this portion by the occupant is visible. Since it is lowered, the shade 31 cannot be clearly recognized, and the portion corresponding to each rectangular region 10T of the second rectangular region group T looks bright, and the visibility of the shade 31 of this portion by the occupant is improved, so the shade 31 becomes clear. Can be recognized. Therefore, since the incident direction of the light with respect to each convex part 41 according to the position of the light source is different, the degree of reflection of each convex part 41 changes. Therefore, the portion corresponding to each rectangular area 10S of the first rectangular area group S and the first The appearance of the portion corresponding to each rectangular area 10T of the two rectangular area groups T changes. Even if the light source position is fixed, if the viewing direction (Z1 direction) for viewing the instrument dial 1 by the occupant is different, the degree of reflection of each projection 41 even if the incident direction of light on each projection 41 is constant. Changes, the appearance of the portion corresponding to each rectangular region 10S of the first rectangular region group S and the portion corresponding to each rectangular region 10T of the second rectangular region group T changes.

  As a result, the reflected light from the instrument dial 1 incident on the eyes of the occupant is changed depending on the direction in which the occupant visually recognizes the instrument dial 1 and the change in the incident direction of the light incident on the instrument dial 1. Therefore, it is possible to approximate the actual appearance of the carbon interior part due to the change in the incident direction and the viewing direction, that is, to increase the real feeling.

  Moreover, the dial 1 for instrument which concerns on this embodiment has the base material 2 which has permeability | transmittance between the printing layer 3 and the clear layer 4 interposed. Therefore, when the occupant sees from the viewing side, the printed layer 3 is viewed through the clear layer 4 and the base material 2, and the thickness from the viewing side surface of the dial 1 for the instrument to the printed layer 3 increases. And it can be approximated to the thickness from the surface of the visual recognition side in a prepreg to carbon fiber. As a result, when an operator looks at the dial 1 from the viewer side, the depth feeling can be improved, and the actual appearance is further approximated to the actual appearance of the carbon interior parts, that is, the real feeling is further increased. can do.

  In addition, in this embodiment, although the dial 1 for instruments was demonstrated as a vehicle interior component, a vehicle interior component is not limited to this. The vehicle interior part may be any one or more of an instrument panel, a console box, an armrest, a roof console, a pillar trim, a door trim, a trunk trim, and the like, for example.

  Moreover, in this embodiment, although each layer was laminated | stacked in order of the printing layer 3, the base material 2, and the clear layer 4 toward the visual recognition side from the other side, it is not limited to this. FIG. 7 is a partial cross-sectional view of a vehicle interior part according to a modification. As shown in FIG. 7, an instrument dial 1 as an interior part for a vehicle is formed by laminating a printing layer 3 on the viewing side of the base material 2 and laminating a clear layer 4 on the viewing side of the printing layer 3. It may be. In this case, if the base material 2 is installed in the ink jet printer, the printing layer 3 and the clear layer 4 can be formed without moving the base material 2, so that the clear layer 4 can be easily positioned with respect to the printing layer 3. It can be carried out. Therefore, the deviation of the clear layer 4 with respect to the print layer 3 can be suppressed at the time of manufacturing the instrument dial 1. Further, in this case, if the vehicle interior part is not required to transmit light from the side opposite to the viewing side of the base material 2 to the viewing side like the dial 1 for the instrument, the base material 2 is transmissive. May not be included.

  Moreover, although each rectangular area | region 10 in this embodiment changes darkly continuously toward a 1st direction or a 2nd direction, it is not limited to this. Each rectangular area 10 may repeat the dark side or the light side toward the first direction or the second direction. Each rectangular region 10S may continuously change so that the central portion in the longitudinal direction is on one side of the light and shade, and both end portions in the longitudinal direction are on the other side of the light and shade. For example, each rectangular region 10S may continuously change so that the central portion in the longitudinal direction is on the dark side and both end portions in the longitudinal direction are on the light side.

  Moreover, in this embodiment, although each convex part 41 was made into the semicylindrical shape, it is not limited to this. FIG. 8 is a perspective view showing a convex portion of a vehicle interior part according to a modification. As shown in FIG. 8, each convex portion 42 is formed such that the length L1 in the shade change direction is longer than the length L2 in the convex portion arrangement direction, and the outer shape 42a and the convex portion when viewed from the shade change direction. Both outer shapes 42b when viewed from the arrangement direction may be formed in a curve. In this case, the curvature of the outer shape 42a when viewed from the light and shade changing direction is smaller than the curvature of the outer shape 42b when viewed from the convex arrangement direction. Even in this case, the reflection state is different between the light incident on the convex portion 42 from the light shade change direction and the light incident from the convex arrangement direction, and the light incident on the convex portion 42 from the light shade change direction is More light than the light incident from the part arrangement direction is reflected toward the constant reflection direction.

  In the present embodiment, each rectangular area 10 is rectangular, but the present invention is not limited to this. For example, each rectangular area 10 may be a square. In the prepreg pattern in which a carbon fiber knitted into a plain weave is impregnated with a resin, the portion of the carbon fiber that is exposed on the viewing side is square (substantially square). That is, the carbon-tone pattern M can be approximated to a pattern of a prepreg in which carbon fibers knitted into a plain weave are impregnated with a resin because each rectangular region 10 is a square. Therefore, the dial 1 for an instrument can be approximated to the actual appearance of a carbon interior part containing plain weave carbon fibers.

  In addition, the printing layer 3 in the present embodiment may be formed with a plurality of rectangular shades 31 corresponding to the convex portions 41 facing each other in the viewing direction in each rectangular region 10 in the convex portion arrangement direction.

  Moreover, in the said embodiment, although the area | region corresponding to each character part 1b was formed in planar shape among the clear layers 4, the convex part 41 is formed similarly to the pattern formation area | region where the carbon tone pattern M is formed. May be. Moreover, the clear layer 4 does not need to be formed in each character part 1b.

  In the printing layer 3 according to the present embodiment, a plurality of straight lines parallel to the density change direction may be formed in each rectangular region 10 in the convex arrangement direction. The color of each straight line is a color that can be recognized as a straight line with respect to the light and shade 31, and is preferably the color on the dark side in the light and shade change direction of the light and shade 31. In this case, among the shades 31 of each rectangular area 10, between adjacent straight lines and between the straight line and the end in the convex portion arrangement direction of the rectangular area 10 are partitioned, and the partitioned part is in the shade change direction. It extends into a band shape and forms a pattern corresponding to one carbon fiber in the carbon-tone pattern M. Therefore, the carbon-tone pattern M can be approximated to one carbon fiber in the prepreg. Thereby, the actual appearance can be further approximated to the actual appearance of the carbon interior part, that is, the real feeling can be further increased. Moreover, it is preferable that each straight line is respectively formed facing the boundary R of the adjacent convex part 41 in the visual recognition direction. In this case, when the instrument dial 1 is desired to be viewed from the viewing side, the straight line can be visually recognized between the adjacent convex portions 41. Therefore, in the carbon-like pattern M, the sectioned band-like portion and the convex portion 41 can be seen more integrally, so that it can be approximated to the three-dimensional shape of one carbon fiber in the prepreg, particularly the carbon fiber. . Thereby, the actual appearance can be further approximated to the actual appearance of the carbon interior part, that is, the real feeling can be further increased.

  In the above embodiment, the case of the instrument dial 1 alone has been described. However, the instrument dial 1 may be formed integrally with the dial. In this case, the base material 2 is formed in a quadrangular shape (including a substantially quadrangular shape), and not only the dial 1 for the instrument but also the printed layer 3 has the carbon-like pattern M on the printed layer 3 and the convex portions 41 and 42 on the clear layer. Is formed.

1 Dial for instruments (Vehicle interior parts)
2 Base material 3 Print layer 31 Shading 4 Clear layer 41, 42 Protrusion 10, 10S, 10T Rectangular area M Carbon tone R Boundary S First rectangular area group T Second rectangular area group

Claims (4)

A substrate;
Printed layer formed on the base material and formed with a carbon pattern,
A laminated layer on the viewing side with respect to the base material, and a transparent layer having transparency,
With
The printed layer is
A plurality of rectangular regions that are color schemes according to the carbon color and whose shade changes along the shade change direction,
The first rectangular region group in which the shade change direction is the first direction and the rectangular regions adjacent to each other in the second direction orthogonal to the first direction are shifted in the first direction;
A second rectangular region group in which the shade change direction is the second direction, and adjacent rectangular regions in the first direction are shifted in the second direction;
Are arranged alternately,
In the clear layer, a plurality of convex portions are formed in a convex portion arrangement direction orthogonal to the light and shade change direction according to each rectangular region,
Each of the convex portions is formed such that the length in the shade changing direction is longer than the length in the convex arranging direction, and at least the outer shape when viewed from the shade changing direction is formed in a curve. Vehicle interior parts. The interior part for a vehicle according to claim 1,
Each of the rectangular regions in the first rectangular region group changes continuously dark toward the first direction,
Each of the rectangular regions in the second rectangular region group changes continuously dark toward the second direction,
A vehicle interior part in which a dark side of each rectangular region of the second rectangular region group is opposed to a dark side of each rectangular region of the first rectangular region group. The vehicle interior part according to claim 1 or 2,
The rectangular area is a rectangle,
The shading change direction is a long side direction of the rectangular region. In the interior component for vehicles according to any one of claims 1 to 3,
The substrate has permeability,
The printed layer is formed on a side opposite to the viewing side with respect to the base material. The vehicle interior component is a vehicle interior component that is an instrument dial.