(Mirror Surface)
A mirror surface, together with a half mirror layer that will be described later, acts to generate a luminous image that provides a stereoscopic effect or a sense of depth. So long as a mirror image can be generated by projecting a luminous image of characters by employing a light emitting unit, which will be described later, the material and the reflectivity of the mirror surface are not particularly limited. It should be noted, however, that a high reflectivity for the mirror surface is preferable, so that a clear mirror image can be generated. For this purpose, a material, such as Al (aluminum), or Ag (silver), or an alloy of them, can be employed for forming the secular face.
When a translucent layer is formed as a light guidance member, as will be described later, specular processing is performed for the lower face of the translucent layer, so as to obtain the mirror surface of the present invention. Specifically, to prepare the mirror surface, vapor deposition is used to form a material, such as Al, on the lower face of the translucent layer.
An Al plate on which the specular processing has been performed, or a resin plate on which a specular material has been deposited or coated, may also be prepared, and the surface of this plate may be employed as a mirror surface.
Generally, a flat, mirror surface is employed; however, the mirror surface is not limited to a flat face. Part of a mirror surface, for example, or an entire mirror surface may be curved in order to provide a variety of luminous displays.
(Half Mirror Layer)
The half mirror layer is located above the mirror surface. According to the display device of this invention, the side where the half mirror layer is formed is used as the observation face side (the design face side). And located between the mirror surface and the half mirror layer is a translucent layer. Therefore, the mirror surface, the translucent layer and the half mirror layer are arranged in this order toward the observation face.
When the display device of this invention is not in the display state, or when the external illuminance is high, as in the daytime, the observation face of the display device assumes a metallic appearance. Therefore, since when not in the display state the inside of the display device can not be seen, the unsightly appearance of a design that may appear when the display device is not in the display state can be eliminated, and a unique design employing a metallic color can be provided. On the other hand, when the display device is in the display state, a luminous image of characters, for example, can be seen through the half mirror layer. As described above, when not in the display state is shifted to in the display state, the tone and the texture on the observation face side are greatly changed, and at the same time, characters, for example, appear. As a result, surprising effects can be produced.
A metal layer (e.g., Al, Ag or Au) having a predetermined film thickness can be employed as the half mirror layer. Or, a metal layer and a protective layer made of a light transmitting resin may also be laminated to form the half mirror layer. An example method for forming this half mirror layer will be described. First, a metal layer composed of an Al thin film is deposited. This metal layer should have sufficient thickness to provide half mirror effects, i.e., a thickness such that the transmittance of light is from about 15 to 20%. Sequentially, printing or coating deposition is employed to apply to and overlay the metal layer with a protective layer of a transparent resin, such as an epoxy resin. The structure of the half mirror layer and its formation method are not limited to these, and another well known structure and method can also be employed. Further, an ink layer may also be formed either on the surface of the protective layer or between the metal layer and the protective layer. Printing or the deposition of a coating can be employed to apply an ink layer of yellow ink, for example.
(Translucent Layer)
The translucent layer is formed of a light guidance layer or by using air. In this invention, the translucent layer may be formed using air, as mentioned above, or two or more translucent layers may be prepared. In the second case, a translucent layer made of a light guidance member and a translucent layer prepared using air may coexist.
The material of the light guidance member is not especially limited, so long as a light transmitting material, and preferably, a transparent material is employed to form the light guidance member. Further, it is preferable that the light guidance member be made of a material that can easily be processed and that is superior in durability. An example material for the light guidance member can be a polycarbonate resin, an acrylic resin, such as a methacrylic resin (PMMA), an epoxy resin or glass. Further, a well known injection molding method can be employed for processing the light guidance member.
(Light Emitting Unit)
The light emitting unit is arranged, between the mirror surface and the half mirror layer, at a position at a distance from the mirror surface, and makes a luminous form consisting of: desired characters, such as arbitrary hiragana, katakana or Chinese characters or alphabetical letters; numbers, such as Arabic or Chinese numbers; symbols, such as mathematical or map symbols; figures, such as circles, triangles or quadrilaterals; or an arbitrary combination of the foregoing forms (hereinafter collectively referred to as a character set). Preferably, surface emission is performed for a specific character set in order to obtain great decorative effects and high visibility. In this invention, a predetermined distance is maintained between the luminous area and the specular area. Therefore, the luminous image of the character set is projected onto the mirror surface, and a mirror image is generated. The predetermined distance is, for example, 2 mm to 10 cm, although in this case it is not especially limited. When too short a distance is used, the effects of the invention, i.e., presentation of a display form with stereoscopic effects and a sense of depth, are not satisfactorily produced. On the other hand, since this distance is affected by the thickness of the display device, too long a distance is also not preferable. The distance set should be within a range of 3 mm to 5 mm.
According to one aspect of this invention, an area for forming a character set, i.e., a luminous area, is located at a distance from both the mirror surface and the half mirror layer. That is, a predetermined distance is also ensured between the luminous area and the half mirror layer. Therefore, a luminous image can be generated with stereoscopic effects and a sense of depth can be better presented. To set the distance in this case, as well as the distance between the luminous area and the mirror surface, both the effects provided by the invention and the thickness of the display device should be taken into account. The distance should be, for example, 2 mm to 5 mm, and preferably 2 mm to 3 mm.
According to an aspect of this invention, a reflection and diffusion area, having the form of a character set, and a light source that projects light onto the reflection and diffusion area are prepared as a light emission unit. In this embodiment, a character set is rendered luminous by light received from the light source. The reflection and diffusion area is formed on the surface or in the inside of the light guidance member, and with this arrangement, light emitted by the light source is transmitted, via the light guidance member, to the reflection and diffusion area. The positional relationship of the light source and the light guidance member is not especially limited, and the light source, for example, can be located opposite the end face of the light guidance member. According to this arrangement, light that has entered at the end face of the light guiding face is guided to project the reflection and diffusion area. The light source may be embedded (in-molding) in the light guidance member. According to this arrangement, the light guidance member can also serve as a waterproof member for the light source. This arrangement is also an effective one for downsizing.
An example method for forming the reflection and diffusion area on the surface of the light guidance member can be surface roughing that uses, for example, sand blasting, etching or electric discharge machining, vapor deposition, coating or printing performed with a light reflecting/diffusing material, or the adhesion of a light diffusion film or tape. Further, an example method used to form a reflection and diffusion area inside the light guidance member can be laser processing or film in-molding. When the above described translucent layer is formed of a light guidance member, the translucent layer (or a part of it) can be employed as the light guidance member described here. It should be noted that, regardless of the structure of the translucent layer, the light guidance member here may also be prepared separately from the translucent layer.
The light source type is not especially limited; however, an LED lamp is preferable because small size, low power consumption and long service life are desirable objectives. An arbitrary type of LED lamp, such as a cannonball type or a chip type, can be employed. As an additional merit for the employment of an LED lamp as a light source, little heat will be generated by the light source, and the thermal affect on peripheral members can be reduced.
The color of the light emitted by the light source is also not especially limited. A plurality of light sources that emit different colors of light can also be employed. When multiple light sources are employed, in various modes, light can be projected by controlling the light emitting state of the light sources. For example, when red, green and blue LEDs are employed as light sources, and the light emitting states and the emitted light quantities of these LED lamps are controlled, a light having a desired color can be emitted. The number of LED lamps to be employed can be determined by considering, for example, the size of a light guidance member and the required luminance level.
According to this aspect of the invention, a set of characters are luminously displayed by using light emitted by the light source. According to another aspect of the invention, a character set rendered that is voluntarily luminescent. For example, an organic EL (electronic luminescence) surface emission element can be employed for a character set. By using the organic EL element, the thickness of a display device and the consumption of power can be reduced. The basic structure of an organic EL element is such that a Hall transport layer, a light emitting layer and an electron transport layer can be formed between a transparent electrode (anode) and a rear electrode (cathode) (see, for example, JP-A-2002-124391). An organic EL element having a structure other than this can also be employed for this invention (see, for example, JP-A-11-102166, JP-A-2001-332389, JP-A-2004-111158 or JP-A-2005-353504).
A display device 1 according to the embodiment of the present invention is shown in
In the display device 1, a first light guidance member 10, a second light guidance member 20, a half mirror film 30 and a protective plate 40 are laminated, in this order, toward the observation face side (above in the figure), and this laminated structure is stored in a cover 60. The individual members, such as the first light guidance member 10, of the structure are rectangular members having substantially the same shape in plan view. The first light guidance member 10 is made of an acrylic resin and has a thickness of a bout 3 mm. A character area 11 having a desired form (characters CAR in this embodiment) is formed in a part of the upper face of the first light guidance member 10. By employing a blasting process, a reflection and diffusion property can be provided for the character area 11. On the other hand, since Al is uniformly deposited on the reverse face of the first light guidance member 10, a mirror surface 12 can be prepared that contacts the reverse face of the first light guidance member 10.
As well as the first light guidance member 10, the second light guidance member 20 is made of an acrylic resin and has a thickness of about 3 mm. The half mirror film 30 is adhered to the upper face of the second light guidance member 20.
A light source 50 is located at a position opposite the end face of the first light guidance member 10. The light source 50 is an LED lamp of a cannonball type (a lens type that emits an umber colored light. When the display device 1 is mounted in a vehicle, power is supplied via a harness to the LED lamp 50. Further, a power control circuit (not shown) is also connected to the LED lamp 50, so that the LED lamp 50 can be turned on or off, interacting, for example, with the ON/OFF state of a side-marker light. In this embodiment, light enters at the right and left end faces of the first light guidance member 10, and two LED lamps are employed. However, the number of LED lamps can be changed as needed. Further, instead of light entering at the two end faces of the first light guidance member 10, as in this embodiment, various entry methods can be employed, e.g., light may enter only at either the right or the left end face, or light may enter at the top and the bottom end faces, as well as at the right and left end faces.
The protective plate 40, which is overlaid on the half mirror film 30, is made of a polycarbonate resin and is prepared so as to protect the half mirror film 30 and to prevent the entry of dust and water. In order to obtain satisfactory dust exclusion and waterproofing effects, the upper edges of the protective plate 40 are connected to the cover 60 using a sealing member, without any gap.
The cover 60 is made of a stainless steel (SUS), and has a thickness of about 0.5 mm. In one face of the cover 60, except near one of the edges, a rectangular opening is formed, and in the display device 1, a luminous character display is presented through this opening. The cover 60 serves as a protective member, and is also an important element in the design of the display device 1. In this embodiment, as described above, stainless steel is employed for the cover 60, so that the cover 60 matches the metallic tone and texture of the half mirror film 30.
The display style of the display device 1 having the above arrangement will now be described. During a period, such as the daytime, wherein the external illuminance is high, the display device 1 enters a no display state (the light source 50 is in the OFF state). At this time, on the observation face of the display device 1 (excludes the cover 60), a metallic tone and texture display appears as a result of the performance of the half mirror film 30. During a period of low external illuminance, such as at night, when the light source 50 is turned on, light emitted by the light source 50 enters the first light guidance member 10, interacting with light emitted as a result of the ON state of the side-marker light (the display state of the display device 1). Then, the light is guided along the inside the first light guidance member 10, and projects the character area 11 that is formed on the upper face of the first light guidance member 10. As a result, the character area 11 becomes luminous, and the surface emission image of the characters (CAR) is directly projected, or is projected by being reflected in the half mirror film 30, and a mirror image is generated on the mirror surface 12. This mirror image is thereafter reflected by the half mirror film 30 and a new mirror image is produced. The generation and reflection of a mirror image using the mirror surface 12 and the half mirror film 30 is repeated, and as a result, a plurality of luminous images (luminous characters) 13, contiguous from the front to the rear, can be observed, as shown in
Furthermore, when the display device 1 is shifted from the no display state to the display state, characters suddenly appear because of the function of the half mirror film 30. Therefore, at the moment the shifting to the display state is effected, surprising effects can also be obtained.
In this embodiment, all the characters (CAR) are displayed using the same style. However, more variety in the display form can be provided by revising the formation of the character area. For example, when a reflection and diffusion method is changed for each character, a different luminous style can be obtained between characters. In addition, as shown in
Another embodiment of the present invention is shown in
For the display device 2, an EL element 70 is employed for luminously displaying characters. The EL element 70 has a structure wherein a rear electrode layer, a dielectric layer, a light emitting layer and a transparent electrode layer (ITO) are laminated in order. Further, a protective layer made of a translucent film is deposited under the rear electrode layer and on the transparent electrode layer. As shown in
In the display device 2, the EL element 70 is located between a first light guidance member 10 and a second light guidance member 20. On the whole, the display device 2 has a structure obtained by laminating a mirror surface 12, the first light guidance member 10, the EL element 70, the second light guidance member 20, a half mirror film 30 and a protective plate 40.
The design of the display device 2 in the no display state (during which the EL element 70 emits no light) is the same as that in the first embodiment, i.e., a metallic design is presented by the function provided by the half mirror film 30. On the other hand, in the display state, the EL element 70 emits light, and the following display style is presented. That is, the surface-emitting image of characters (CAR) is repetitively reflected by the half mirror film 30 and the mirror surface 12, and accordingly, a mirror image is generated. As a result, as well as in the first embodiment, multiple luminous images (luminous characters), contiguous from the front to the rear, are observed. As described above, the display device 2 also provides a display style having a great decorative effect and a high sense of quality. Furthermore, surprising effects can also be produced using the function of the half mirror film 30. It should be noted that the thickness of the display device 2 is reduced by using the EL element 70.
The preferred embodiments of the present invention have been described. However, employment of the display device of the invention is not limited to the scuff plate portion of an automobile, and can also be applied and used decoratively for various other portions, e.g., the display of a logo mark at a center cluster, steering wheels, a back garnish, doors and pillars. Further, the present invention can be applied not only for decorating automobiles, but also for display plates for various types of vehicles and display plates used for the interior and exterior of buildings such as houses and offices. Also, the present invention can be applied for decorations for the ceilings of vehicles or buildings. For this usage, in addition to the decorative effects, a sense of depth and space can be provided, or a sense of spaciousness can be produced. In this manner, the invention can also be employed as means for producing spatial effects.
The present invention is not limited to the aspects and the embodiments of the present invention. Furthermore, without departing from the subject described in the claims, this invention also includes various other modifications that one having ordinary skill in the art can easily determine are appropriate.
The contents of papers, Japanese patent applications laid open and granted patents enumerated in this specification should be employed by being cited.
Number | Date | Country | Kind |
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P. 2006-250434 | Sep 2006 | JP | national |