JP5515712B2 - Light emitting device - Google Patents

Description

The present invention relates to electrical equipment for gaming machines that emits light from a light guide, an indicator, an electrical decoration signboard, a sign, a guide plate, decorative lighting, and illumination.

When a reflective function process that reflects light is applied to the back surface of a highly transparent light guide such as an acrylic resin, a light source is placed on the end face of the light guide and the light is incident on the inside of the light guide. The light emitted to the outside from the region subjected to the process appears to shine. Light-emitting devices using such a principle have already been used in various fields such as interior decoration lighting for cars, signboards, guide boards, signs, etc., starting with the lighting equipment for gaming machines.

The basic principle of such a light guide is shown in FIG. The light emitted from the light source 1 enters the light guide 2 from the incident end face 3. The incident light repeatedly transmits internal reflections with the air interface. If the front and back surfaces of the light guide that are reflected here are smooth and light scattering does not occur and the front and back surfaces are parallel, the light is totally reflected and is not emitted to the outside. That is, it doesn't look shining. On the other hand, when the light transmitted through the light guide reaches the light emitting region 6, the traveling direction of the light is changed and emitted to the outside by the reflection function processing 4 formed in the light emitting region. This makes it look shining. By forming the shape of the light emitting region on a pattern or character to be emitted, a light emitting device that emits light of the shape of the pattern or character can be manufactured. The reflection function treatment can be broadly divided into a method of changing the traveling direction of light depending on the uneven shape of the light guide surface, and a light diffusion layer containing filler is formed by printing and diffused and reflected by multiple reflections in the diffusion layer. There is a method of changing the traveling direction of light.

In the light emitting region, the light flux density in the light guide is transmitted while being emitted to the outside, so that it gradually decreases. However, it is possible to cause the entire light emitting region to shine with uniform brightness by forming it by appropriately changing the reflection function treatment so that the intensity of reflecting light is inversely proportional and gradually increased. Alternatively, when such a structure is not adopted, the light emission region emits light that gradually becomes darker as the distance from the light source increases.

Such a light guide manufacturing method includes a method of printing white ink on the surface of the light guide, a method of cutting grooves, a method of forming unevenness with a laser, a method of simultaneously forming an uneven shape by injection molding, and light diffusion. A method of forming a layer by extrusion molding simultaneously with a transparent light guide is known.

The light guide is made to emit light by arranging the light source on the end face of the light guide thus produced, and the light guide emits light. As the light source, an LED that is small and excellent in high-speed blinking is particularly suitable. For example, if a multi-color LED having red, blue, and green diode chips contained in one package is used, the overall color can be variously changed. If LEDs are arranged at both short ends of the long light guide and light is emitted in different colors, light can be emitted such that the colors from both ends change in a gradation toward the center. In addition, when the light guide has a rod shape that is gently curved so as not to destroy the total reflection as shown in FIG. 2, the light repeatedly transmits the internal reflection along the curve. If a light emitting area is formed, it is possible to make a device in which a curved rod-shaped light guide shines. Thus, the light-emitting device using a light guide can be applied to various shapes, has a feature capable of performing various light emission effects, and is used in various applications. However, in the light emitting device using the conventional light guide, light emission of one fixed shape is performed for each light guide, and only the effect due to the color change or blinking can be performed. In particular, dynamic effects are desired for use as an electrical decoration device for gaming machines.

As an example of performing a dynamic effect, Patent Document 1 proposes a light emitting device that stacks a plurality of light guides and LEDs to perform dynamic effect light emission. In this apparatus, it is necessary to arrange a plurality of light guides and to have a complicated structure in which LEDs are arranged for each light guide. For this reason, there are drawbacks that it is costly, and the boundaries between the individual light guides can be recognized by an observer, and the principle of light emission is simple, so that there are disadvantages in that it is not surprising or novel.

JP 2007-109554 A

The present invention has been made in view of such circumstances, and an object of the present invention is to provide a low-cost light-emitting device capable of providing a dynamic, versatile and innovative production.

The present invention is a light emitting device having a light guide and a light source disposed at each of two ends AB thereof, and at least two kinds of fine prisms are arranged on the back surface of the light guide by performing a reflection function process. The first fine prism is formed so that the light incident from the end A is emitted toward the viewer and the light incident from the end B is not emitted toward the viewer. The prism emits light incident from the end B in the direction of the observer and does not emit light incident from the end A in the direction of the observer. The height of the light source is changed separately depending on the position, and the light emission region, color and brightness pattern can be changed by controlling the light emission color and light emission intensity of the light sources arranged at both ends AB. It is the light-emitting device characterized.

The invention according to claim 2 is that the two kinds of fine prisms both have an asymmetric triangular cross section having two reflecting surfaces, and the angle formed by the first reflecting surface and the normal direction is 70 degrees to 87 degrees. The light emitting device is particularly preferable in that the angle formed by the second reflecting surface and the normal direction is in the range of 35 to 50 degrees, and the two types of microprisms have a mirror image relationship.

In addition to the above-described two types of micro prisms, the invention of claim 3 is provided with a third micro prism that emits light incident from either the end A or the end B toward the viewer. A light emitting device characterized by the above.

According to the light emitting device of the present invention, it is possible to provide a dynamic, versatile and innovative illumination effect for an observer.

FIG. 1 is a side view illustrating the basic principle of a light emitting device using a light guide. FIG. 2 is a diagram for explaining the principle of light transmission in a curved rod-shaped light guide. FIG. 3 is a side view illustrating the configuration of the first embodiment. FIG. 4 is a side view illustrating the light emission state of the first embodiment. FIG. 5 is a side view for explaining the behavior of light in a fine prism. FIG. 6 is a side view illustrating the light emission state of the second embodiment. FIG. 7 is a side view for explaining the behavior of light in a fine prism. FIG. 8 is a side view illustrating the light emission state of Example 3. FIG. 9 is a front view illustrating the configuration of the fourth embodiment. FIG. 10 is a front view for explaining the light emission state of the symbol. FIG. 11 is a front view illustrating the light emission state of the symbol FIG. 12 is a front view showing an embodiment using a curved rod-shaped light guide. FIG. 13 is a diagram showing a cross-sectional shape of a rod-shaped light guide

FIG. 3 is a side view for explaining the characteristics of the basic embodiment of the light emitting device according to the present invention. An LED light source 1a is arranged close to the upper end surface A of the light guide and 1b is arranged close to the lower end surface B. Two kinds of fine prisms 5a and 5b having a linear ridge line parallel to the incident side are formed on the back surface of the light guide. The cross-sectional shape of the fine prism is an asymmetric triangle, and the fine prisms 5a and 5b have a mirror image relationship. The surface of the fine prism has high smoothness and has specular reflectivity. In this embodiment, the fine prism 5a is formed in the light emitting area 6a, and the fine prism 5b is formed in the light emitting area 6b.

In Example 1, the behavior of light in a state where the upper LED light source 1a emits light is shown in FIG. 4A, and the behavior of light in the state where the lower LED light source 1b emits light is shown in FIG. 4B. . The light incident from above is emitted when the direction is changed to the direction near the normal when it reaches the fine prism 5a formed in the light emitting region 6a, but is oblique when it reaches the fine prism 5b formed in the light emitting region 6b. The light is emitted downward. When the observer is near the normal, only the light emitting region 6a appears to shine. (FIG. 4A). On the other hand, the light incident from below is emitted in the direction near the normal when it reaches the fine prism 5b formed in the light emitting region 6b, but obliquely upward when it reaches the fine prism 5a formed in the light emitting region 6a. It is emitted in the direction. When the observer is near the normal direction, only the light emitting region 6b appears to shine. (FIG. 4B).

Here, each microprism has such a small size that its three-dimensional shape cannot be recognized by observation with the naked eye, and the difference between 5a and 5b is hardly distinguishable. For this reason, the observer cannot imagine the principle that the light emission changes between the regions, and the light emitting device impresses the unexpectedness and novelty.

In the light emitting region, the light flux density in the light guide is transmitted while being emitted to the outside, so that it gradually decreases. However, by gradually decreasing the pitch of the fine prisms, gradually increasing the height of the fine prisms, or gradually changing both, it is possible to illuminate the entire light emitting region with uniform brightness. Alternatively, when such a structure is not adopted, the light emission region emits light that gradually becomes darker as the distance from the light source increases.

FIG. 5A and FIG. 5B are enlarged side views for explaining the detailed operation of one fine prism. The fine prism 5 a has two reflecting surfaces, a reflecting surface 7 and a reflecting surface 8. As shown in FIG. 5A, the light from above is reflected by the reflecting surface 7, then reflected by the reflecting surface 8, and emitted to an angle near the front side (observer side) normal. Further, some light does not reach the reflection surface 7 but directly reaches the reflection surface 8, but this light is not reflected by the reflection surface 8 but is emitted to the back surface.
On the other hand, the light from below reaches the reflecting surface 7 directly as shown in FIG. Among them, some of the light is emitted to the back surface, and some of the light is reflected by the reflecting surface 7 but hardly emitted to the outside. A part of the light is reflected by the reflecting surface 7 and emitted from the surface. At this time, the emission angle is greatly inclined upward from the normal direction.

In order to achieve such light behavior, the angle between the reflecting surface 7 and the reflecting surface 8 is important, and the angle α formed with the normal direction of the reflecting surface 8 is preferably in the range of 70 to 87 degrees. If α is smaller than 70 degrees, light from below is emitted at an angle close to the normal direction, which is not preferable. On the other hand, if α is larger than 87 degrees, the pitch interval of the prism becomes wider, and Since the interval becomes too wide, the ratio of emitting light from above in the normal direction becomes small and the display becomes dark, which is not preferable. Further, the angle β formed with the normal direction of the reflecting surface 8 is preferably in the range of 35 to 50 degrees in order to emit light from above in the front normal direction.
Note that the appropriate ranges of α and β shown here are for the case where the observation direction is the normal direction, and in the case where the observation direction is inclined from the normal direction, the appropriate values vary. Specifically, when the observation direction is tilted downward, α is decreased and β is increased. When the observation direction is tilted upward, α is increased and β is decreased.
The fine prism 5b can be described in the same manner except that it is inverted up and down with respect to 5a, and will be omitted.

FIG. 6 is a side view for explaining the features of another embodiment of the light emitting device according to the present invention. In the first embodiment, two types of fine prisms are formed on the back surface of the light guide plate, whereas in the second embodiment, three types of fine prisms including these are formed. That is, the fine prism 5a is formed in the light emitting region 6a, the fine prism 5b is formed in the light emitting region 6b, and the third fine prism 5c is formed in the light emitting region 6c. The fine prism 5c has a symmetrical trapezoidal shape, and both light from above and light from below emit light in the direction near the normal line. Therefore, when the observer is in the vicinity of the normal direction, the light emitting areas 6a and 6c appear to shine when the upper LED 1a emits light, and the light emitting areas 6b and 6c appear to shine when the lower LED 1b emits light.

FIGS. 7A and 7B are enlarged side views for explaining the detailed function of one microprism 5c. The fine prism 5c has a reflecting surface 9a, a reflecting surface 9b, and a flat surface 10. As shown in FIG. 7A, the light from above is reflected by the flat surface 10, then reflected by the reflecting surface 9b, and emitted to an angle near the front side (observer side) normal. On the other hand, as shown in FIG. 7B, the light from below is reflected by the flat surface 10 and then reflected by the reflecting surface 9a to be emitted to an angle near the front side (observer side) normal. In order to reflect light in the normal direction, the angle γ is preferably in the range of 20 to 35 degrees.

In the light emitting device of the present invention, by using multi-color light emitting LEDs in which red, blue, and green diode chips are housed in one package at both ends of the light guide, and by individually changing the light emission color of the LEDs, Various colors can be produced. As an example, a description will be given in a situation where light of different colors is incident from above and below the light guide having the structure taken up in the second embodiment. When red light is incident from above and blue light is simultaneously incident from below, the region 6a appears red, the region 6b appears blue, and the region 6c receives red and blue light. It appears to shine in a mixed magenta color. According to the same principle, when red light is incident from above and green light is incident simultaneously from below, the region 6a appears red, the region 6b appears green, and the region 6c is red. It appears to glow yellow with a mixture of green and green light. According to the same principle, when blue light is incident from above and green light is simultaneously incident from below, the region 6a appears blue, the region 6b appears green, and the region 6c appears blue. And green light appear to shine in mixed cyan. As described above, the light emitting device of the present invention uses multicolor light emitting LEDs, and various and novel effects that have been impossible until now are possible.

FIG. 8 is a side view illustrating another embodiment of the light emitting device according to the present invention. In the third embodiment, the two types of fine prisms 5a and 5b are not formed in separate areas, but are formed by mixing them together, and the formation density of the respective fine prisms changes. When light enters from above or below the light guide, selective reflection of light in the observation direction from the fine prism 5a and the fine prism 5b occurs according to the same principle as in the first embodiment. By changing the light emission intensity of the upper and lower LEDs, it is possible to produce an effect in which the brightness distribution in the light emitting region changes.

FIG. 9 is a light-emitting device using the basic structure of Example 2, that is, a light guide that forms three types of microprisms, and observation of a light-emitting device that displays specific symbols by applying the three types of microprisms. The aspect seen from the person side is shown with the front view. The light guide has a plate shape with a constant thickness, and a fine prism is formed only on the back surface area of the two circular symbols, and the other areas are mirror surfaces on the front and back surfaces. The fine prism 5a is formed in the region 6a, the fine prism 5b is formed in the region 6b, and the fine prism 5c is formed in the region 6c so as to form a ridge line parallel to the incident surface. (The lines in the region are hatching for identifying the region and do not indicate the direction of the fine prism ridge line.) Moreover, it is preferable that the inclined reflecting surfaces 11 are formed on both sides of the LED light incident part.

FIG. 10 is a front view for explaining the light emission state of the light emitting device. When the left LED emits light, the regions 6a and 6c appear to emit light as shown in FIG. This makes the left circle appear to shine. Here, the inclined reflecting surface 11 has a function of reflecting a light beam incident on the light guide and having a large angle with the incident surface, and directing the light beam in the pattern direction. When the right LED emits light, the regions 6b and 6c appear to emit light as shown in FIG. This makes the right circle appear to shine. When the LEDs on both the left and right sides emit light, as shown in FIG. 10C, all the regions 6a, 6b, and 6c appear to shine. As a result, two circular symbols appear to shine.

FIG. 11 shows a light emission state in a light emitting device in which the light emitting devices of Example 4 are connected in parallel as an application example. In this case, various effects can be performed by causing the light from the four LEDs to emit only one circular symbol corresponding thereto.

FIG. 12 shows an example in which the LEDs 1 are arranged at two ends of a gently curved rod-shaped light guide, and an example in which the basic structure of Example 2 is modified. (The line in the region is hatching for identifying the region and does not indicate the direction of the fine prism ridge line.) The ridge line direction of the fine prism is formed so as to be orthogonal to the curved outline of the light guide. In this embodiment, since the traveling direction of light is transmitted along the curve as described in FIG. 2, when the left LED emits light, the regions 6a and 6c appear to emit light, and the right LED emits light. Sometimes the regions 6b and 6c appear to emit light, and when the LEDs on the left and right sides emit light, all the regions 6a, 6b and 6c appear to emit light. Thus, by bending the rod-shaped light guide into a desired shape, it is possible to emit a pattern or a character with the shape of the light guide itself.

The cross-sectional shape of the rod-shaped light guide may be a square as shown in FIG. 13A, but the cross-sectional shape in which the reflection curved surface 12 is formed on both sides of the surface on which the fine prism is formed as shown in FIG. A cross-sectional shape in which the convex lens exit surface 13 is formed on the viewer side as shown in FIG. In the case of a quadrangular cross-sectional shape as shown in FIG. 13A, outgoing light spreads in the cross-sectional direction and is emitted in FIG. 13B due to the reflecting action of the reflective curved surface 12, and FIG. In c), the reflected light from the fine prism is condensed and emitted in the normal direction by the refracting action of the emission surface 13. For this reason, higher normal luminance is realized. In applications where the observation direction is limited, it is preferable to have a cross-sectional shape that collects outgoing light in the observation direction.

In using the light emitting device of the present invention, since the light guide serving as the light emitting effect portion is transparent and the back can be seen through, the degree of freedom that can be arranged in front of various display mechanisms such as electronic display devices, printed patterns, etc. Have. Moreover, it is also possible to have a configuration in which a plurality of light guides are arranged in multiple layers, and LEDs are arranged on the end surfaces of the respective light guides. In this case, by turning on / off the LEDs of each layer individually or changing the emission color, it is possible to dynamically display different designs or produce multicolored emission in multiple layers.

When the diffuse reflective member is disposed in close contact with the back surface of the light guide, the light emitted from the fine prism to the back surface is diffusely reflected by the reflective member. This diffuse reflected light is observed regardless of the intended effect light emission, and the light emission contrast is weakened. For this reason, it is desirable to avoid as much as possible that the diffuse reflective member is closely arranged on the back surface of the light guide.

In a general application, a structure in which the LED or the light guide incident portion is directly visible to the observer is not desirable because the light source portion appears dazzling and is not desirable aesthetically. For this reason, it is desirable to arrange a light shielding cover on the front side of the LED, the substrate on which the LED is arranged, and the light guide incident portion.

The light guide used in the present invention can be mass-produced at low cost by preparing a mold and performing injection molding. The fine prism shape can be processed on the mold with high smoothness and high precision by cutting using the corresponding tip-shaped cutting tool (bite). Transfer formed on the light guide.

If the arrangement pitch of the micro prisms is too large, each micro prism will be visually recognized as a line, so it is desirable that the pitch be as fine as possible to create a high-definition feeling. Since the exact shape is sometimes not transferred, a range of approximately 0.1 mm to 1 mm is preferred. As the material of the light guide, one having a high transmittance at the emission wavelength of the LED to be used is desirable, and an acrylic resin, a polycarbonate resin, a cycloolefin resin, or the like is preferably used.

The light-emitting device of the present invention is preferably used as an electrical decoration device that exhibits various and dynamic effects in various gaming machines. Moreover, it is applicable also to an indicator, an electrical decoration signboard, a sign, a guide board, decorative lighting, illumination, and the like.

1 Light source (LED)
2 Light guide plate 3 Entrance end face 4 Reflective pattern 5 Fine prism 6 Light emitting region 7 Reflective face of fine prism 8 Reflective face of fine prism 9 Reflective face of fine prism 10 Plane face of fine prism 11 Inclined reflective face 12 Reflective curved face 13 Convex lens exit face

Claims (2)

A light-emitting device having a light guide and light sources arranged at two opposite ends A and B, wherein at least three kinds of fine prisms are arrayed on the back surface of the light guide, The first micro prism reflects and emits the light incident from the end A toward the viewer, and does not emit the light incident from the end B toward the viewer. The light incident from B is reflected and emitted in the direction of the observer, and the light incident from the end A is not emitted in the direction of the observer. Is changed separately depending on the position, and in addition to the two types of fine prisms, a third prism is formed that emits light incident from either the end A or the end B toward the viewer, Emission color and emission intensity of light source arranged at opposite end portions AB Emitting device characterized by capable of changing the pattern of areas, color and brightness of the light guide emitting by the control. The first microprism and the second microprism according to claim 1 both have an asymmetric triangular cross section having two reflecting surfaces, and an angle between the first reflecting surface and a normal direction is 70 degrees to 87. The angle between the second reflecting surface and the normal direction is in a range of 35 degrees to 50 degrees, and the two kinds of fine prisms are in a mirror image relationship. Light-emitting device.

Images