JP2009037968A - Mini lamps and light fixtures - Google Patents

Abstract

[PROBLEMS] To provide a small lamp with sufficient brightness and long life, and to prevent the small lamp from being reflected on the lens cover when the small lamp is mounted. Providing lighting that looks great from the outside.
A semi-transparent metal thin film 10 formed so as to cover a top part 11t of a glass bulb 11 has a maximum outside dimension of the glass bulb 11 A and a maximum outside dimension closest to the top part 11t of the glass bulb 11. When the dimension from the part to the top part 11t is B, the dimension relationship B <A / 2 is established.
[Selection] Figure 1

Description

  The present invention relates to a small lamp used for an automobile illumination lamp, a display lamp, and the like, and a lamp mounted with the small lamp.

  A stop lamp device and a turn signal lamp device, which are used when the vehicle starts, changes its course, turns left or right, and the like, are provided on the front and rear portions and side surfaces of a vehicle such as an automobile. These various lamp devices emit red and orange signals by flashing the lamp, and can inform the driver of the following vehicle and the oncoming vehicle of information such as the start situation of the own vehicle and the course change.

  Usually, the stop lamp device and the turn signal lamp device use an incandescent lamp using a transparent glass bulb as a light source, using a lens cover colored amber or red. A reflecting mirror that reflects the light from the light source toward the lens cover is disposed to form a lamp.

  In recent years, the lens cover has been made of a clear transparent material that is colorless and transparent or white and transparent. Due to demands for improving the design of vehicles, a small lamp bulb can be made of colored glass as a light source. Increasing use of small lamps that emit light in orange or red when light is transmitted through the colored layer when the lamp is turned on, such as by forming a colored film on the glass bulb or covering it with a colored heat-resistant synthetic resin cap .

  This light source is mainly a bulb or glass tube colored amber or red. Therefore, while the light source is turned off, the appearance color of the light source is reflected in the lens cover made of a colorless and translucent material. In addition, in the case of a bulb using transparent glass for a small lamp, the filament, which is a constituent member of the small lamp, can be seen, which makes the design unsatisfactory.

  In addition, when external light such as sunlight is inserted into the lamp, the internal structure of the lamp is reflected on the clear lens cover due to reflection by the reflecting plate and becomes more conspicuous. In addition, it is emphasized by the reflector, and from the outside, it looks as if the small lamp is lit, and there are cases where the surrounding driver misidentifies.

From these situations, a method of mounting a top cover that covers a light source incorporated in a lamp is disclosed as a measure for preventing reflection on the lens cover. (For example, see Patent Document 1)
Also, as a measure to prevent reflection on another lens cover, a half-mirrored metal thin film such as aluminum or silver, which is the same color as the lamp reflector, is coated or evaporated from the bulb top to a part of the bulb straight part. A small lamp is also disclosed. (For example, see Patent Document 1 or Patent Document 2)
Normally, the top shape of the small lamp is formed in a semispherical shape. As a result, the intensity of light emitted from the filament that is the light emission center is such that the same brightness can be obtained even if the angle is changed somewhat when viewed from the top of the small lamp. It is formed in a semi-spherical shape.

  7A is a schematic diagram of a side shape from the top portion of the conventional small lamp to the middle portion, and FIG. 7B is a plan view of the top portion of the bulb 31 of the small lamp 30 as shown in the plan view thereof. In the small lamp 30 in which the shape of 33 is formed in a hemispherical shape, the intermediate portion 31n of the bulb 31 is formed in a straight line from the top portion 31t of the bulb 31, and the top portion 31t is equivalent to a reflector of a lamp not shown. In the case of a small lamp 30 coated or vapor-deposited with color aluminum or the like, assuming that the maximum width of the small lamp 30 is A and the length of the coating or vapor deposition in the tube axis direction is B, in either case, B = A The relationship is / 2.

  In addition, as shown in FIG. 8, when the intermediate portion 31n of the bulb 31 of the small lamp 30 is formed with a curved line, the relationship of B = A / 2 is established.

  In addition, as a measure to prevent small lamps from appearing on the lens cover, a small part is coated or vapor-deposited with aluminum that is the same color as the lamp reflector from the top of the bulb to a part of the bulb's straight part (intermediate part). There is an example of a lamp.

Further, as a countermeasure for preventing the small lamp from being reflected on the lens cover, there is an example in which semi-transmissive aluminum or the like having the same color as the lamp reflector is coated or deposited on the entire bulb portion or the top portion of the bulb.
JP 2002-500814 A JP 2002-110107 A

  However, as a measure to prevent the small lamp from appearing on the lens cover, in the case of a method of attaching a top cover that covers the light source incorporated in the above-mentioned lamp, the lamp becomes expensive due to an increase in parts and man-hours. End up.

  In addition, as a measure to prevent the small lamp from appearing on the lens cover, in the case of a small lamp coated or vapor-deposited, such as aluminum, which is the same color as the lamp reflector, from the bulb top to a part of the straight portion of the bulb, Since the coating portion or the like does not transmit light and is close to a light source (filament), the transmittance is deteriorated. Therefore, it is necessary to increase the light emission amount of the small lamp, and as a result, the life of the small lamp is shortened.

  In addition, as a measure to prevent the small lamp from appearing on the lens cover, when the entire bulb part of the small lamp or semi-transparent aluminum with the same color as the lamp reflector is coated or deposited on the bulb top part, Since the deposited film becomes thin, the durability of the film is inferior, and the coating part may be peeled off during lighting.

  The present invention has been made based on these circumstances, and prevents a small lamp having sufficient brightness and a long life, and a small lamp from being reflected on the lens cover when the small lamp is mounted. It is an object of the present invention to provide a lamp that has good visibility and that looks good from the design.

The small lamp according to the embodiment of the present invention is characterized by a glass bulb formed of colored glass or glass coated with a colored coating, a light source provided inside the glass bulb, and the top of the glass bulb. A small lamp having a semi-transparent metal thin film formed over a portion,
When the maximum outer dimension of the glass bulb is A and the dimension from the maximum outer dimension closest to the top portion of the glass bulb to the top portion is B, the semi-transparent metal thin film has B <A That is, it is formed so that a dimensional relationship of / 2 is established.

The lamp according to the embodiment of the present invention is characterized in that a socket to which a small lamp is mounted, a reflecting mirror formed of a concave mirror having an opening extending from the position of the socket, and the opening is covered. A lamp having a translucent lens cover disposed,
The socket is capable of mounting the small light bulb described above.

  A small lamp with sufficient brightness and long life, and when the small lamp is mounted, it prevents the small lamp from being reflected on the lens cover, has good visibility from the outside, and looks great from the design side. It is possible to realize a lamp that works.

  BEST MODE FOR CARRYING OUT THE INVENTION The best mode for carrying out the small lamp of the present invention and a lamp using the same will be described below with reference to the drawings.

  In the present invention, there are various types of small lamps, but since the lamps to which the small lamps are attached are common, the lamps will be described first.

  FIG. 1A is a side sectional view in the longitudinal direction of a lamp with a small lamp mounted thereon, FIG. 1B is a side sectional view in the short direction, and FIG. 1C is a front view thereof.

  A lamp 1 provided at the front or rear of a vehicle and used as a brake small lamp, a turn signal small lamp, or a stop small lamp has a socket 3 for fixing a small lamp 2 as a light source, and a bottom of a concave reflecting mirror 4. Is provided. The opening 5 of the reflecting mirror 4 is covered with a plate-shaped lens cover 6.

  As will be described later in detail, the small lamp 2 is a wedge-base type having a colorless and transparent glass bulb (hereinafter simply referred to as a bulb, denoted by reference numeral 11 in FIG. 2) or a small lamp 2 with a base.

  The socket 3 is a socket 3 that receives and fixes a wedge base portion or a base of the small lamp 2 and is connected to a power supply line, or a socket 3 attached to a printed wiring board or the like (in this case, the power supply line is Unnecessary).

  The reflecting mirror 4 is a concave mirror having a curved curved reflecting surface, and a reflecting surface 7a is formed on a base body 7 formed separately from a metal plate or a synthetic resin material or integrally formed with both. A reflective film 8 made of aluminum or the like is formed on the reflective surface 7a.

  The positional relationship between the end 5a of the opening 5 of the reflecting mirror 4 and the small lamp 2 is such that the filament 9 cannot be seen from the outside as shown by line A in FIGS. 1 (a) and 1 (b). Become. Therefore, the position of the end 5a of the opening 5 of the reflecting mirror 4 depends on the position of the small lamp 2 inside the lamp 1, the position of the filament 9 that is the light source for each small lamp 2, etc. The position is set so that the filament 9 is not visible from the outside.

  1 (a) and 1 (b), the filament 9 is displayed so that the stretched state can be seen, but in an actual attachment state, either one is rotated by 90 degrees.

  The lens cover 6 is formed of a material such as synthetic resin or glass provided so as to cover the opening 5 of the reflecting mirror 4. For example, it is a colorless and transparent translucent heat-resistant acrylic resin. On the outer surface of the lens cover 6, a translucent metal thin film 6a having a white half mirror action is formed.

  As a material for forming the translucent metal thin film 6a having a half mirror action, in addition to silver Ag, aluminum Al, molybdenum Mo, titanium Ti, tantalum Ta, platinum Pt, palladium Pd, gold Au, chromium Cr, or alloys thereof are used. It can be used as a main component.

  In addition, as another structure of the translucent metal thin film 6a, what formed the multilayer optical interference film which consists of an oxide of the metal from which refractive index differs can be used. That is, a material mainly composed of oxides such as titanium Ti, tantalum Ta, zirconium Zr and niobium Nb having a relatively high refractive index and compounds of these oxides, and silicon Si having a low refractive index relative to these materials. A translucent metal thin film comprising a multi-layered optical interference film by preparing an oxide or a material mainly composed of this oxide and coating the surface of the lens cover 6 or colored thin film with this high and low refractive index material alternately. 6a can be obtained.

  The translucent metal thin film 6a can be formed by means such as vacuum deposition, sputtering, spraying, dipping, sol-gel, electrostatic coating, ion plating, or CVD. Further, the film thickness is preferably uniform over the entire formation surface, but may vary partially as desired or non-formed portions may exist. Further, the surface of the translucent metal thin film 6a may be in a glossy state having a mirror surface or in a semi-glossy state such as a satin finish.

  In the case of the lamp 1 having the above-described configuration, the small lamp 2 emits orange light when the small lamp 2 inside the lamp 1 is lit. The direct light of the emitted light and the reflected light from the reflecting mirror 4 (indicated by an arrow in FIG. 1A) are colorless and transparent lens cover 6, and a translucent metal formed on the surface of lens cover 6 Orange light is radiated out of the lamp 1 through the silver Ag thin film, which is the thin film 6a. Further, when the small lamp 2 is turned off, the translucent metal thin film 6a is formed on the outer surface of the lens cover 6 in the same manner as the lamp 1, so that it acts as a half mirror, and the colored small lamp 2 inside is not externally visible. Even if it is not visible, a slight shadow is produced.

  Therefore, in the case of the lamp 1 described above, it is possible to radiate a predetermined light color such as orange from the small lamp 2 colored through the colorless and transparent lens cover 6 from the small lamp 2.

  In the lamp 1, the translucent metal thin film 6 a made of a white half mirror is formed on the lens cover 6. Therefore, when the lamp is turned off, the lens cover 6 is passed through to mount the external shape of the small lamp 2 and the filament 9. Even if the member is not visible, even if it is present, it is possible to prevent a slight decrease in appearance.

  That is, since the transparent metal thin film 6 a is formed on the surface of the lens cover 6, it is possible to prevent the colored small lamp 2 and the colored color from being reflected on the reflecting mirror 4. When a strong external light is incident, the small lamp 2 will no longer appear to be lit, reducing the risk that the driver of the following vehicle or the oncoming vehicle will misunderstand whether the small lamp 2 is lit or not. In addition, road safety can be improved.

  In the above case, the lens cover 6 is a colorless transparent translucent heat-resistant acrylic resin. The lens cover 6 has an outer surface on which a translucent metal thin film 6a having a white half mirror action is formed. However, when the small lamp 2 described later is used, the translucent metal thin film 6a is Only a colorless and transparent translucent heat-resistant acrylic resin plate that is not formed can be used.

  Even in such a case, as described above, the positional relationship between the end 5a of the opening 5 of the reflecting mirror 4 and the small lamp 2 is the filament from the outside as shown by line A in FIGS. 1 (a) and 1 (b). Since the position is such that 9 cannot be visually recognized, the filament 9 is not visually recognized from the outside. Therefore, the appearance is not impaired from the design aspect.

  Next, the small lamp 2 used as a light source will be described.

  FIG. 2 shows a small lamp 2 used in a vehicle turn signal lamp apparatus as an example of the small lamp 2 according to the present invention. For example, a partially sectional front view of a small lamp 2 colored with a wedge base rating of 12 V and 25 W is shown. is there.

  The small lamp 2 has a lower end portion of a tube-shaped (T-shaped) bulb 11 made of an orange transparent soda-lime glass or the like formed by adding an orange pigment made of a mixed oxide of molybdenum Mo and sulfur S as a glass component. A wedge-shaped sealing portion 12 formed by crushing and sealing is formed. A pair of lead wires 13, 13 hermetically sealed inside the sealing portion 12 and extending to the inside and outside of the bulb 11 are arranged, and the internal lead wires 13 extending to the inside of the bulb 11 are arranged, Between 13, a coiled filament 9 wound with a tungsten fine wire as a light emitting source is stretched.

The outer or inner surface of the top portion 11t is a top of the valve 11, for example, chromium Cr, trilayer or film formed of aluminum Al and silicon oxide SiO _2, or is formed by depositing silver (Ag) It is a semi-transparent metal thin film 10 made of a white half mirror, and the thickness of the top portion 11t of the bulb 11 is 30 to 70 nm (300 to 700 mm) thick film 6b, and the side surface (intermediate portion) 11n side of the bulb 11 Was thinned to 5 to 50 nm (50 to 500 mm). That is, the top portion 11t is formed thicker than the side surface (intermediate portion) 11n of the bulb 11. (In FIG. 2, the semi-transparent metal thin film 10 is shown with exaggerated thickness dimensions for easier discrimination than the other portions.)
The valve 11 is filled with an inert gas such as argon Ar at a predetermined pressure.

  The small lamp 2 formed by thinning the semi-transparent metal thin film 10 that forms a white system in this manner by thinning the side near the sealing portion 12 from the side surface 11n with respect to the top portion 11t of the bulb 11 is the top of the bulb 11 at the time of lighting. The semi-transparent metal thin film 10 at the portion 11t has high light absorption (reflectance) and low transmittance, but the intermediate portion 11n has low luminance and high transmittance as compared with the top portion 11t. Therefore, the small lamp 2 can prevent a decrease in luminous efficiency.

  The light emission color of the small lamp 2 is within the range of preferable orange light emission in the CIE chromaticity coordinates, for example, y ≦ x−0.120, y ≧ 0.390, y ≦ 0.790−0.670x. And within the range of preferable white light emission of 0.500 ≧ x ≧ 0.310, y ≦ 0.150 + 0.640x, y ≧ 0.050 + 0.750x, 0.440 ≧ y ≧ 0.382. As described above, if a colored film or a semi-transparent metal thin film 10 is formed by selecting a material, a film thickness, or the like, a material that emits a preferable orange light can be obtained.

  In the small lamp 2 described above, the bulb 11 is formed of colored glass with an orange colored layer, but is not limited to colored glass. For example, in a dispersion solution in which a solvent such as an orange pigment, a dispersant, a silicone polyester resin, and ethyl acetate is stirred and mixed. A colorless and transparent glass bulb 11 is dipped and pulled up, the coating liquid is dried, and then baked to form a colored film having a substantially uniform film thickness on the outer surface. The translucent metal thin film 10 may be formed by changing the film thickness.

  Further, the color of the glass of the transparent colored glass bulb 11 of the small lamp 2 and the colored coating formed on the surface of the colorless and transparent glass bulb 11 are not limited to the above-mentioned orange color, but are used for red, fog lamps and the like used for stop lamps and the like. It may be yellow or the like used.

  Next, an embodiment of the shape of the top of the small lamp 2 will be described.

(Embodiment 1)
Fig.3 (a) is a side surface schematic diagram of the side shape from the top site | part of the small lamp | ramp of Embodiment 1 to an intermediate part, (b) is the model top view. The light-shielding film is formed on the top of the small lamp 2 of the first embodiment, and the shape is A, where the maximum external dimension of the bulb 11 of the small lamp 2 is A. If the dimension up to the top part 11t of the valve 11 is B, a dimensional relationship of B <A/2 is established, and the shape of the top part 11t of the valve 11 is truncated when the radius R is R> A / 2. It is formed by a spherical surface.

  Therefore, the small lamp 2 of the first embodiment is compared with the conventional small lamp 2 when the total length of the small lamp 2 is the same as that of the conventional small lamp 2 compared to B = A / 2. Since the area of the side surface 11n having a small light absorption (reflectance) and a high transmittance compared to the top portion 11t is widened, a higher luminance can be exhibited as compared with a conventional small lamp.

  FIG. 3A shows a case where the intermediate portion 11n of the valve 11 is a cylindrical shape formed with a straight line. However, as shown in the schematic side view of FIG. 4, the intermediate portion 11n of the valve 11 has a curved surface. The same applies to the case formed by the above.

(Embodiment 2)
FIG. 5A is a side schematic view of the side shape from the top part to the middle part of the small lamp of Embodiment 2, and FIG. 5B is a plan view thereof. A light-shielding film is formed on the top of the small lamp 2 of the second embodiment, and the shape is A from the maximum outer dimension of the bulb 11 of the small lamp 2 and the maximum outer dimension closest to the top portion 11t of the bulb 11. If the dimension up to the top part 11t of the valve 11 is B, a dimensional relationship of B <A / 2 is established, and the shape of the top part 11t of the valve 11 is flattened. Is formed.

  Therefore, the small lamp 2 of the second embodiment is compared with the conventional small lamp 2 when the total length of the small lamp 2 is the same as that of the conventional small lamp 2 when B = A / 2. Since the area of the side surface 11n having a small light absorption (reflectance) and a high transmittance compared to the top portion 11t is widened, a higher luminance can be exhibited as compared with a conventional small lamp.

  FIG. 5A shows the case where the intermediate portion 11n of the valve 11 is a cylindrical shape formed with a straight line. However, although not shown, the same applies when the intermediate portion 11n of the valve 11 is formed with a curved surface. It is.

(Embodiment 3)
FIG. 6A is a schematic side view of a side shape from the top part to the middle part of the small lamp according to the third embodiment, and FIG. 6B is a plan view thereof. A light shielding film is formed on the top of the small lamp 2 of the third embodiment, and the shape is A, where the maximum external dimension of the bulb 11 of the small lamp 2 is A, and from the maximum external dimension portion closest to the top portion 11t of the bulb 11. If the dimension up to the top part 11t of the valve 11 is B, a dimensional relationship of B <A / 2 is established, and the shape of the top part 11t of the valve 11 is formed in a concave surface. The angle of the light emitted from the filament 9 is changed by the concave reflecting surface 7a. Thereby, since the light quantity to the reflective surface 7a of the reflecting mirror 4 of the lamp 1 can be increased, the utilization efficiency of the light from the small lamp 2 can also be improved.

  Compared with the conventional small lamp 2, the small lamp 2 of the third embodiment is the top when compared to the conventional small lamp 2 when the total length of the small lamp 2 is the same as that of the conventional small lamp 2 B = A / 2. Since the area of the side surface 11n having a small light absorption (reflectance) and a high transmittance is larger than that of the portion 11t, it is possible to exhibit higher brightness than that of a conventional small lamp.

  FIG. 6A shows the case where the intermediate portion 11n of the valve 11 is a cylindrical shape formed with a straight line. However, although not shown, the same applies when the intermediate portion 11n of the valve 11 is formed with a curved surface. It is.

Actually, with respect to the small lamp 2 of the above-described first to third embodiments, the luminous flux was measured with a spherical photometer (integrating sphere), and as a result, the total luminous flux of the entire small lamp with no coating on the small lamp 2 was 100%. And when
(1) The change rate of the total luminous flux of the small lamp coated with the top part of the conventional product is about 70%.

  (2) The small lamps of Embodiments 1 to 3 were confirmed to have a change rate of the total luminous flux of about 85%.

  Therefore, if the small lamps 2 of Embodiments 1 to 3 have the same total luminous flux with the same life as the conventional product, the power consumption can be reduced.

  In addition, the small lamps 2 of the first to third embodiments can have a longer life if the total power consumption is the same with the same total luminous flux as that of the conventional product.

  In addition, the small lamps 2 of Embodiments 1 to 3 can reduce peeling due to discoloration and a decrease in film bonding force due to oxidation of the light shielding film even at the end of the life. And various advantages.

  Furthermore, the lamp using the small top lamp of Embodiments 1 to 3 has an appearance of the lamp on the lens cover by applying a light-shielding silver thin film to the surface of the top portion of the bulb using transparent glass or colored glass. The colors and bulbs are prevented from being reflected, and the uncomfortable feeling when the lights are turned off is suppressed. Moreover, misrecognition due to the insertion of external light can be reduced, leading to prevention of traffic accidents and improving safety.

  In addition, the lens cover of the lamp such as the rear combination of the car and the side marker can be manufactured only by clearing, so that the lamp looks good. In addition, the inner lens (dark blue, red) of the lamp and the top part cover of the light source are not required, and an economical effect can be expected in that the cost can be reduced by reducing the number of parts and man-hours.

  Note that the present invention is not limited to the above-described embodiments as they are, and can be embodied by modifying the constituent elements without departing from the scope of the invention in the implementation stage. Moreover, various inventions can be formed by appropriately combining a plurality of constituent elements disclosed in the above embodiments. For example, some components may be deleted from all the components shown in the embodiment. Furthermore, constituent elements over different embodiments may be appropriately combined.

(A) is a sectional side view in the longitudinal direction of a lamp with a small lamp mounted, (b) is a sectional side view in the short direction, and (c) is a front view thereof. The present invention is a partial sectional front view of a small lamp. (A) is the side surface model of the side shape from the top site | part of the small lamp | ramp of Embodiment 1 of this invention to an intermediate part, (b) is the top view. (A) is the side surface model of the side shape from the top site | part of the small lamp | ramp of Embodiment 1 of this invention to an intermediate part, (b) is the top view. The side surface model of the side shape from the top site | part of the modification of the small lamp of Embodiment 2 of this invention to the intermediate part. (A) is a side surface schematic diagram of the side shape from the top part of the small lamp of Embodiment 3 of this invention to an intermediate part, (b) is the top view. (A) is a side schematic diagram of a side shape from the top part to the middle part of a conventional small lamp, and (b) is a plan view thereof. The side surface model of the side shape from the top site | part to the intermediate part of the modification of the conventional small lamp.

Explanation of symbols

  DESCRIPTION OF SYMBOLS 1 ... Lamp, 2 ... Small lamp, 3 ... Socket, 4 ... Reflector, 5 ... Opening, 6 ... Lens cover, 6a ... Translucent metal thin film, 6b ... End part, 7 ... Base | substrate, 7a ... Reflecting surface, 8 DESCRIPTION OF SYMBOLS ... Reflective film, 9 ... Filament, 10 ... Semi-transparent metal thin film, 11 ... Glass bulb, 11t ... Top part, 11n ... Middle part, 12 ... Sealing part, 13 ... Lead wire.

Claims (2)

A glass bulb formed of colored glass or glass coated with a colored coating; a light-emitting source provided inside the glass bulb; and a translucent metal thin film formed to cover the top portion of the glass bulb; A small lamp having
When the maximum outer dimension of the glass bulb is A and the dimension from the maximum outer dimension closest to the top portion of the glass bulb to the top portion is B, the semi-transparent metal thin film has B <A A small lamp characterized by being formed so that a dimensional relationship of / 2 is established. A lamp having a socket to which a small lamp is mounted, a reflecting mirror formed by a concave mirror having an opening extending from the position of the socket, and a translucent lens cover arranged to cover the opening. And
The said socket can mount | wear with the small lamp | ramp of Claim 1.

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