JP2019117260A - Resin molding, and transparent cover, radiator grille and door molding using the same - Google Patents

Abstract

To provide a resin molding which enables decoration with color without coating, and a transparent cover, a radiator grille and a door molding using the same.SOLUTION: A resin molding is used for a vehicle. The resin molding has a base material 30 and an interference layer 50. The base material 30 is formed of a resin. The interference layer 50 is laminated on one end face 31 of the base material 30 and is formed of indium, when light from the outside is incident, base material reflection light Lr_B, surface reflection light Lr_S and internal reflection light Lr_I interfere. The resin molding measures molding reflectance that is light reflectance to a reflected light wavelength being each wavelength of the reflected light, and has the maximum value of the molding reflectance at a reflection light wavelength of 400 nm to 500 nm in plotting at the reflection light wavelength and the molding reflectance.SELECTED DRAWING: Figure 6

Description

  The present disclosure relates to a resin molded body, a transmission cover using the same, a radiator grill and a door molding.

  Conventionally, as described in Patent Document 1, a black pigment and a blue pigment are blended, and the blended pigment is applied to a substrate formed of a black resin to give a color tone to the substrate It is known to decorate a substrate.

JP, 2016-22411, A

  In a resin molded body used for a vehicle, after forming a metal film on a resin molded body, color clear coating may be applied to the metal film in order to give a color tone to the resin molded body. In the case of performing color clear coating on the metal film with a compounded pigment as in Patent Document 1, it is necessary to control the coating film thickness to which the color clear coating is applied, since the color varies depending on the film thickness. As the variation in coating film thickness increases, color unevenness is likely to occur.

  An object of the present disclosure is to provide a resin molded body that can be decorated with color without color clear coating, a transmission cover using it, a radiator grille, and a door molding.

The present disclosure is a resin molded body (1) used for a vehicle (10). The resin molding comprises a substrate (30) and an interference layer (50).
The substrate is formed of a resin.
The interference layer is laminated on one end face (31) of the base material, and is formed of indium, and when light from the outside is incident, light (Lr_B) reflected on one end face of the base material, the surface (52) The reflected light (Lr_S) and the light reflected inside (53) (Lr_I) interfere.
When the resin molded product measures the reflectance (Ri) of light to the reflected light wavelength (λr) which is each wavelength of the reflected light, and plots the reflectance of light to the reflected light wavelength and the reflected light (Ri) to the reflected light wavelength In addition, the reflected light wavelength has a maximum value (Rv) of the reflectance of light with respect to the reflected light wavelength at 400 nm to 500 nm.

  The resin molded product has a blue interference color and is in a decorated state. As a result, it is not necessary to color clear the resin molded body 1 in order to give the resin molded body a color tone, and the color variation is eliminated. Therefore, the resin molded product can be decorated with colors without being color clear-painted. In addition, since color clear coating is not required, it is not necessary to consider variations in the coating film thickness.

Moreover, this indication is a permeation | transmission cover (12) which used the said resin molding.
The transmission cover is provided on the vehicle (10), and includes the transparent member (121), the cover substrate (122), and the above-mentioned interference layer provided between the transparent member and the cover substrate.
The transparent member is made of resin and can transmit radio waves and light.
The cover substrate is made of resin and is formed on the inner side of the vehicle than the transparent member. The permeable cover of the present disclosure exhibits the same effects as the above-described resin molded product.

Furthermore, the present disclosure is a radiator grille (20) using the resin molded body.
The radiator grill includes a frame (21), an air introducing portion (23) and a partition member (22).
The frame forms an outer frame.
The air introducing portion is provided inside the frame, has an air flow path (26) communicating in the front-rear direction of the vehicle, and can introduce air from the outside.
The partition member is provided inside the frame to define the air flow path. The frame and the partition member are formed of the resin molded body. The radiator grille of the present disclosure exhibits the same effects as the resin molded body.

Moreover, this indication is a door molding (71, 72) using the said resin molding.
The door molding is provided along the door (16, 17) of the vehicle (10) and can protect the door when the door is opened and closed. The door molding is formed of the resin molded body. The door molding of the present disclosure exhibits the same effects as the above-described resin molded product.

BRIEF DESCRIPTION OF THE DRAWINGS The block diagram of the vehicle provided with the permeation | transmission cover and the radiator grille which used the resin molding by one Embodiment. BRIEF DESCRIPTION OF THE DRAWINGS The block diagram of the permeation | transmission cover using the resin molding by one Embodiment, and the radar apparatus for vehicles. III part enlarged view of FIG. Sectional drawing of the resin molding by one Embodiment. The schematic diagram for demonstrating the measuring method of the light transmittance of the interference layer of the resin molding by one Embodiment. The schematic diagram for demonstrating the interference by the interference layer of the resin molding by one Embodiment. The related view of the reflected light wavelength of the resin molding by one Embodiment, and a molded object reflectance. The relationship figure of the interference layer thickness and maximum value of the resin molding by one Embodiment. The relationship figure of the base material reflectance and local maximum of the resin molding by one Embodiment. The relationship figure of the light transmittance of the interference layer of the resin molding by one Embodiment, and a maximum value. BRIEF DESCRIPTION OF THE DRAWINGS The block diagram of the vehicle provided with the door molding using the resin molding by one Embodiment. Sectional drawing of the resin molding by other embodiment. Sectional drawing of the resin molding of a comparative example.

  Hereinafter, an embodiment of a resin molding will be described based on the drawings. In a plurality of embodiments, substantially the same configuration will be described with the same reference numerals. Moreover, in the case of this embodiment, a plurality of embodiments are included. The resin molded body of the present embodiment is used for a vehicle 10. For example, the resin molded body of the present embodiment is used for the transmission cover 12 and the radiator grille 20 provided in the vehicle 10.

  First, the vehicle 10 used for the resin molded body of the present embodiment will be described. The forward direction of the vehicle 10 is "front". The backward direction of the vehicle 10 is "rear". Also, the upper side is referred to as "upper" when viewed from the forward direction. The lower side is referred to as “down” when viewed from the forward direction. The vertical direction and the vehicle height direction which is the height direction of the vehicle 10 are the same. Further, the right side is taken as "right" when viewed from the forward direction. Let the left side be "left" when viewed from the forward direction. The lateral direction and the vehicle width direction which is the width direction of the vehicle 10 are the same.

  As shown in FIG. 1, the vehicle 10 includes a transmissive cover 12 and a radiator grille 20. The transmission cover 12 is provided on the front side of the radiator grille 20. The radiator grille 20 is provided between the headlights 18.

  As shown in FIG. 2, the vehicle 10 further includes a vehicle radar device 11. The vehicle radar device 11 is provided behind the radiator grille 20. The vehicle radar device 11 can transmit and receive radio waves. For example, millimeter waves are used as radio waves. The vehicle radar device 11 transmits a radio wave, and the transmitted radio wave passes through the transmission cover 12. The vehicle radar device 11 receives radio waves reflected from a target such as a forward vehicle. In the figure, radio waves are indicated by hatching so that the radio waves become clear.

  The vehicle radar device 11 measures the distance, the angle, and the relative velocity from the vehicle 10 to the target by transmitting and receiving radio waves. The distance from the vehicle 10 to the target is measured from the time difference between transmission and reception extracted by correlating the received signal with the appropriate modulation applied to the amplitude, frequency or phase of the transmitted signal. The angle from the vehicle 10 to the target is measured by scanning radio waves while limiting transmission and reception of radio waves to a limited heading. The relative velocity from the vehicle 10 to the target is measured by extracting the frequency shift that occurs in the radio wave reflected by the Doppler effect.

The transmissive cover 12 includes a transparent member 121 and a cover base 122, and a design surface 123 is formed.
The transparent member 121 is provided on the front side of the vehicle 10, is made of resin, and can transmit radio waves or light. Further, the transparent member 121 is formed with a recess.

  The cover base 122 is provided on the rear side of the transparent member 121, and is joined to the front end face 124 of the cover base 122 and the rear end face 125 of the transparent member 121. The cover base 122 has a convex portion. The convex portions of the cover base 122 are provided on the front side of the cover base 122 and at the upper and lower ends of the cover base 122. The shape of the convex portion of the cover base material 122 corresponds to the shape of the concave portion of the transparent member 121, and the convex portion of the cover base member 122 is formed to be engageable with the concave portion of the transparent member 121.

  The transmissive cover 12 has an undercut shape in which the concave portion of the transparent member 121 and the convex portion of the cover base 122 engage with each other, and is formed so that the transparent member 121 and the cover base 122 are not separated. A convex portion may be formed on the transparent member 121, a concave portion of the cover base 122 may be formed, and the convex portion of the transparent member 121 may be engaged with the concave of the cover base 122.

  The design surface 123 is formed on the front end surface 124 of the cover substrate 122, and displays various designs. The design surface 123 is formed by depositing a metal. The base material of the resin molded body of the present disclosure is used for the cover base material 122. Between the transparent member 121 and the cover base 122, an interference layer of the resin molded body of the present disclosure is provided.

As shown in FIG. 3, the radiator grille 20 has a frame 21, a plurality of louvers 22 as partition members, and an air introducing portion 23.
The frame 21 forms an outer frame of the radiator grille 20. Further, the upper portion of the frame 21 is referred to as a frame upper portion 24, and the lower portion of the frame 21 is referred to as a frame lower portion 25.
The plurality of louvers are formed in a plate shape, and provided between the frame upper portion 24 and the frame lower portion 25. The resin molded body 1 is used for the frame 21 and the groove 22.

  The air introduction unit 23 is provided inside the frame 21 and has an air flow passage 26 so that air can be introduced from the outside. The air flow passage 26 is partitioned by a plurality of louvers 22 and communicated in the front-rear direction. In the figure, in order to clarify the location of the air flow path 26, the air flow path 26 is described by a dot pattern.

  Conventionally, as described in Patent Document 1, a black pigment and a blue pigment are blended, and the blended pigment is applied to a substrate formed of a black resin to give a color tone to the substrate It is known to decorate a substrate.

  As shown in FIG. 13, in the resin molded body 90 used for a vehicle, after forming the metal film 92 on the resin base material 91, in order to give a color tone to the resin molded body 90, color clear coating is applied to the metal film 92. There is something to do. When the color clear layer 93 is subjected to color clear coating on the metal film 92 as in the comparative example, color variations occur depending on the film thickness. For this reason, it is necessary to manage the paint film thickness T_ref which is the film thickness of the color clear layer 93. When the variation in the coating film thickness T_ref becomes large in the color clear layer 93, color unevenness easily occurs, and it is difficult to manage the coating film thickness T_ref. So, in this embodiment, the resin molding 1 which can be decorated with a color is provided, without color clear coating.

(One embodiment)
As shown in FIG. 4, the resin molded body 1 includes a base 30, an intermediate layer 41, a coating layer 42, and an interference layer 50.

  The base 30 is formed of a resin, and can reflect light at one end face 31 of the base 30 or inside the base 30. The light reflected by one end face 31 of the substrate 30 is referred to as substrate reflected light Lr_B. Moreover, the base material 30 has a pigment including black particles such as carbon black. Furthermore, the base material 30 is formed so that L value which is a lightness index may be 1.0 or more and 25.0 or less. The L value is a correlation amount of lightness. The L value is measured, for example, by a method in accordance with JIS_Z_8781.

  The intermediate layer 41 is formed on one end surface 31 of the substrate 30 and provided between the substrate 30 and the interference layer 50. The middle layer 41 is formed of a resin and can transmit light. The maximum height roughness of the surface of the intermediate layer 41 is referred to as an intermediate layer roughness Rz_M1. The maximum height roughness of the surface of the substrate 30 is taken as a substrate roughness Rz_B. Each maximum height roughness is a definition based on JIS_B_0601. The apparatus for measuring the maximum height roughness is, for example, a contact-type surface roughness measuring machine using a stylus or the like, or a non-contact type surface roughness measuring machine using a laser or the like. The intermediate layer 41 is formed such that the intermediate layer roughness Rz_M1 is smaller than the substrate roughness Rz_B, that is, Rz_M1 <Rz_B.

  The covering layer 42 is provided so as to sandwich the interference layer 50 with the intermediate layer 41. Similar to the intermediate layer 41, the covering layer 42 is formed of a resin and can transmit light. The covering layer 42 is formed to have the same thickness as that of the intermediate layer 41. The intermediate layer 41 and the covering layer 42 are formed to have a thickness of several μm to several tens of μm.

  The interference layer 50 is laminated on the intermediate layer 41 on the side opposite to the substrate 30, and is made of indium. The interference layer 50 has a plurality of indium particles 51 deposited thereon, and is formed in an island-like structure. The indium particles 51 are located on the surface 52 of the interference layer 50 or in the inside 53 of the interference layer 50. The indium particles 51 are formed in a hemispherical shape and are deposited on the intermediate layer 41. Furthermore, the indium particle 51 has a curved shape at the outer edge in the cross section. In the figure, the indium particle 51 is exaggerated and described.

  The thickness of the interference layer 50 is referred to as an interference layer thickness Ti [Å]. The interference layer 50 is formed to have an interference layer thickness Ti of 50 Å or more and 250 Å or less. In the figure, in order to clarify the location of the interference layer 50, the interference layer 50 is described in white. Also, in the drawing, the intermediate layer 41, the interference layer 50, and the covering layer 42 are exaggeratingly described.

The interference layer 50 is formed such that the light transmittance τ, which is a ratio of the intensity of the transmitted light to the intensity of the incident light, is 10% to 80%.
As shown in FIG. 5, a first transparent layer 61 capable of transmitting light is formed on a transparent resin 60 such as an acrylic resin. In addition, the interference layer 50 is formed on the first transparent layer 61. In the interference layer 50, a second transparent layer 62 capable of transmitting light is formed. The light transmittance τ of the interference layer 50 is measured using the molded body in which the first transparent layer 61, the interference layer 50, and the second transparent layer 62 are formed on the transparent resin 60 as a sample. The first transparent layer 61 and the second transparent layer 62 are formed to have a thickness of several μm to several tens of μm.

  A halogen lamp is used as the light source 63 for the measurement of the light transmittance τ. The light of the light source 63 has a wavelength of 380 nm to 780 nm. The light of the light source 63 is irradiated toward the interference layer 50 and the intensity detector 64. The light from the light source 63 passes through the second transparent layer 62, the interference layer 50, the first transparent layer 61, and the transparent resin 60. The intensity detector 64 detects the intensity of the transmitted light. The ratio of the light intensity detected by the intensity detector 64 to the light intensity of the light source 63 is calculated as the light transmittance τ of the interference layer 50. The distance from the light source 63 to the second transparent layer 62 and the distance from the transparent resin 60 to the intensity detector 64 are about several tens of mm to 100 mm.

  As shown in FIG. 6, light reflected by the interface of the indium particles 51 located on the surface 52 of the interference layer 50 when light from the outside is incident is referred to as surface reflected light Lr_S. The light reflected at the interface of the indium particles 51 in the inside 53 of the interference layer 50 when light is incident from the outside is referred to as internally reflected light Lr_I. Light from the outside transmits through the intermediate layer 41 and the covering layer 42.

  When light from the outside enters the resin molded body 1, the base material reflection light Lr_B, the surface reflection light Lr_S, and the internal reflection light Lr_I interfere with each other. Each wavelength of the reflected light when light from the outside is reflected by the resin molded body 1 is taken as a reflected light wavelength λr. The reflectance of light with respect to the reflected light wavelength λr is taken as the molded body reflectance Ri.

  The shaped body reflectance Ri is measured by spectrophotometry. Light is incident on the resin molded body 1 from a light source. The light reflected by the resin molded body 1 enters the diffraction grating through the slit. The light entering the diffraction grating is separated. The separated light enters a light receiver corresponding to each light to generate a photocurrent. The photocurrent is digitized in the electronic circuit and compared to the white light. The green body reflectance Ri is measured by comparison with white light.

  As shown in FIG. 7, when the molded body reflectance Ri is measured, and the reflected light wavelength λr and the molded body reflectance Ri are plotted, a reflectance curve C which is a curve connecting plotted points is drawn. In the figure, the horizontal axis is the reflected light wavelength λr, and the vertical axis is the molded body reflectance Ri. The reflectance curve C is drawn, for example, by Lagrange interpolation or spline interpolation. When the reflectance curve C is drawn, the resin molded body 1 has the maximum value Rv of the molded body reflectance Ri at the reflected light wavelength λr of 400 nm or more and 500 nm or less. The maximum value Rv is a point at which the slope of the tangent line becomes zero in the reflectance curve C, and is a turning point where the sign of the slope of the tangent line changes from plus to minus as the reflected light wavelength λr increases. FIG. 7 shows the reflectance curve C when the interference layer thickness Ti is set to 150 Å.

[1] When light from the outside is incident, the substrate reflection light Lr_B, the surface reflection light Lr_S, and the internal reflection light Lr_I interfere with each other by the interference layer 50. When the molded body reflectance Ri is measured, and the reflected light wavelength λr and the molded body reflectance Ri are plotted, the resin molded body 1 has the molded body reflectance Ri at the reflected light wavelength λr of 400 nm or more and 500 nm or less. It has a maximum value Rv. For this reason, the resin molding 1 has a blue interference color, and will be in the decorated state.

  As a result, it is not necessary to color clear the resin molded body 1 in order to give the resin molded body 1 a color tone, and the variation in color is eliminated. Therefore, the resin molded body 1 can be decorated with colors without being color clear-painted. Since color clear coating is not required, it is not necessary to consider variations in the coating film thickness. For this reason, control and conditions of manufacture are eased, and the resin molding 1 becomes easy to manufacture.

[2] The interference layer 50 is formed such that the interference layer thickness Ti becomes 50 Å or more and 250 Å or less.
FIG. 8 is a view showing the relationship between the interference layer thickness Ti and the maximum value Rv. As the interference layer thickness Ti increases, the intensity of the substrate reflected light Lr_B decreases, and the intensities of the surface reflected light Lr_S and the internally reflected light Lr_I increase. When light is incident on the resin molded body 1 as the intensity of the surface reflected light Lr_S and the internal reflected light Lr_I increases, total reflection easily occurs in the interference layer 50. Therefore, as the interference layer thickness Ti increases, the maximum value Rv increases.

  Considering the characteristics of the resin molded body 1 of the present embodiment, when the interference layer thickness Ti is 50 Å or more and 250 Å or less, the resin molded body 1 has a maximum at a reflected light wavelength λr of 400 nm or more and 500 nm or less It becomes easy to have value Rv. Therefore, the resin molded body 1 tends to have a blue interference color, and tends to be in a decorated state.

[3] The substrate 30 has a pigment containing black particles. Thus, the substrate reflected light Lr_B having a relatively small energy and a relatively large wavelength is not reflected but easily attenuated or absorbed. For this reason, it becomes easy to reflect base material reflected light Lr_B which has comparatively large energy and has a comparatively short wavelength.

  FIG. 9 is a diagram showing the relationship between the L value and the maximum value Rv. When the L value is 1.0 or more and 25.0 or less, when the L value is 1.0 or more and 25.0 or less, in the case where the reflected light wavelength λr is 400 nm or more and 500 nm or less, when the L value is 1.0 or more and 25.0 or less. It becomes easy to have maximum value Rv. It produces the same effect as the effect of [2].

[4] The interference layer 50 is formed so that the light transmittance τ when formed on the transparent resin 60 having the first transparent layer 61 and the second transparent layer 62 is 10% or more and 80% or less. ing.
FIG. 10 is a view showing the relationship between the light transmittance τ and the maximum value Rv. When the light transmittance τ is relatively small, it is difficult for the light to be transmitted by the interference layer 50. For this reason, when light enters the resin molded body 1, total reflection easily occurs in the interference layer 50. Thereby, the maximum value Rv is relatively large. When the light transmittance τ is relatively large, the interference layer 50 is likely to transmit light. For this reason, total reflection is easily caused by the base material 30, and the influence of the base material 30 is easily generated.

  In the present embodiment, the substrate 30 has a pigment including black particles. Therefore, the substrate reflected light Lr_B having a relatively small energy and a relatively large wavelength is not reflected but easily attenuated or absorbed. Thus, when the light transmittance τ is relatively large, the maximum value Rv is relatively small.

  When the light transmittance τ is 10% or more and 80% or less, when the light transmittance τ is 10% or more and 80% or less, in the case where the reflected light wavelength λr is 400 nm or more and 500 nm or less. It becomes easy to have maximum value Rv. The resin molded body 1 tends to have a blue interference color and tends to be in a decorated state.

[5] The intermediate layer 41 is formed such that the intermediate layer roughness Rz_M1 is smaller than the substrate roughness Rz_B. By the intermediate layer 41, the surface on which the interference layer 50 is deposited is smoothed and leveled. Therefore, when the interference layer 50 is formed, the surface tension generated between the intermediate layer 41 and the interference layer 50 decreases. Therefore, the adhesion between the intermediate layer 41 and the interference layer 50 is improved more than the adhesion between the intermediate layer 41 and the base 30. Thereby, the interference layer 50 is easily formed.

[6] The interference layer 50 is sandwiched between the intermediate layer 41 and the covering layer 42. The internal stress of the interference layer 50 by the covering layer 42 relieves the internal stress of the interference layer 50 by the intermediate layer 41. Therefore, the adhesion of the interference layer 50 is improved.

(Other embodiments)
(I) As shown in FIG. 11, the resin molded body 1 of the present embodiment may be used for door moldings 71 and 72 provided on the doors 16 and 17 of the vehicle 10. The door moldings 71 and 72 are described with dot patterns in order to clarify their locations.

The door molding 71 extends in the vertical direction along the doors 16 and 17 and is provided between the front door 16 and the rear door 17.
The door molding 72 extends in the front-rear direction along the doors 16 and 17 and is provided between the doors 16 and 17 and the locker panel 73.

  The door moldings 71 and 72 are formed in a rod shape, and have a U-shaped, J-shaped, L-shaped or I-shaped sectional shape. The door moldings 71 and 72 include the base 30 and the interference layer 50. The door moldings 71, 72 can protect the ends of the doors 16, 17 and the doors 16, 17 so that the doors 16, 17 are not damaged when the doors 16, 17 are opened and closed.

(Ii) The transparent cover may be provided on the side of the inside of the door of the vehicle or the like. Also, the transmissive cover may be provided at the rear of the vehicle.
(Iii) The roughness of the substrate, the intermediate layer, the covering layer and the interference layer is not limited to the maximum height roughness, but may be the arithmetic average roughness Ra, the average height Rc or the root mean square height Rq, etc. Good.

(Iv) As shown in FIG. 12, the intermediate layer 41 may have a pigment including black particles, as with the substrate 30. Even if the intermediate layer 41 is black, the same effects as in the present embodiment can be obtained. In addition, in FIG. 12, in order to clarify the intermediate | middle layer 41, the intermediate | middle layer 41 is described by a dot pattern.
As mentioned above, this indication is not limited to such an embodiment, It can implement with various forms in the range which does not deviate from the meaning.

1 ··· Resin molded body,
30 ··· Base material, 31 ··· One end surface of base material,
50 · · · interference layer, 52 · · · surface of interference layer, 53 · · · inside of interference layer,
Lr_B ・ ・ ・ Substrate reflection light, Lr_S ・ ・ ・ Surface reflection light,
Lr_I ・ ・ ・ Internally reflected light,
λ r ··· Reflected light wavelength,
Ri ... molded body reflectance, Rv ... maximum value.

Claims (9)

It is a resin molded body (1) used for a vehicle (10),
A substrate (30) formed of a resin,
It is laminated on one end face (31) of the substrate and is formed of indium, and when light from the outside is incident, it is reflected on the surface (52) of light (Lr_B) reflected by one end face of the substrate An interference layer (50) in which the light (Lr_S) and the light (Lr_I) reflected by the inside (53) interfere with each other;
Equipped with
When the reflectance (Ri) of light to the reflected light wavelength (λr) which is each wavelength of the reflected light is measured, and the reflectance (Ri) of light to the reflected light wavelength and the reflected light wavelength is plotted, The resin molding which has local maximum value (Rv) of the reflectance of the light with respect to the said reflected light wavelength in 400 nm-500 nm of reflected light wavelengths.   The resin molded body according to claim 1, wherein the interference layer is formed such that the thickness of the interference layer is 50 Å or more and 250 Å or less.   The resin molded body according to claim 1, wherein the base material has a pigment including black particles.   The method according to claim 1, further comprising: an intermediate layer (41) provided between the substrate and the interference layer, wherein the surface roughness (Rz_M1) is smaller than the surface roughness (Rz_B) of the substrate. The resin molding as described in any one of to 3.   The resin molded body according to claim 4, further comprising a covering layer (42) which is provided so as to sandwich the interference layer with the intermediate layer and can transmit light.   The interference layer has a light transmittance (τ) of 10% or more and 80% or less when formed on a transparent resin (60) having a first transparent layer (61) and a second transparent layer (62). The resin molded body according to any one of claims 1 to 5, which is formed. A transparent cover (12) provided on the vehicle (10),
A transparent member (121) made of resin and capable of transmitting radio waves and light;
A cover base material (122) which is formed of a resin and is formed on the inner side of the vehicle than the transparent member;
It is provided between the transparent member and the cover base material, is made of indium, and when light from the outside is incident, light (Lr_B) reflected by one end face of the cover base material, light reflected from the surface An interference layer (50) with which (Lr_S) and internally reflected light (Lr_I) interfere;
Equipped with
When light from the outside is incident, the wavelength of the reflected light is 400 nm to 500 nm when plotted by the reflected light wavelength (λr) which is each wavelength of the reflected light and the reflectance (Ri) of the light to the reflected light wavelength Transparent cover with maximum value (Rv). A radiator grille (20) provided on a vehicle (10),
A frame (21) forming an outer frame,
An air introduction portion (23) provided inside the frame and having an air flow path (26) communicating in the front-rear direction of the vehicle, and capable of introducing air from the outside;
A partition member (22) provided inside the frame and defining the air flow path;
Equipped with
The radiator grille in which the said flame | frame and the said partition member are formed with the resin molding as described in any one of Claims 1-6. Provided along the door (16, 17) of the vehicle (10), which can be protected when the door is opened and closed,
A door molding (71, 72) formed of the resin molded product according to any one of claims 1 to 6.

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