JP4173524B2 - Tube, tube with reflector, and lighting device - Google Patents

Description

  The present invention relates to a tube, a tube with a reflector, and an illumination device, and more particularly to a technique for improving a filament body in a tube.

A halogen bulb with a reflector, which is a kind of tube with a reflector, is a combination of a reflector having a concave reflecting surface and a halogen bulb, and is used for spot lighting in stores, for example. Yes.
The halogen bulb has a configuration in which a filament body is housed in a hermetically sealed bulb. When a halogen bulb is used in combination with a reflecting mirror, the condensing efficiency can be improved by making the filament body as compact as possible and concentrating the light emitting region at the focal position of the reflecting mirror as much as possible. In this case, it is known that reducing the light emitting region particularly in the optical axis direction of the reflecting mirror is effective for improving the light collection efficiency.

  However, generally, when the rated voltage [V], rated power [W], and rated life (for example, 3000 hours) of a halogen bulb are determined, the diameter of the tungsten wire constituting the filament body is The length is substantially determined. Therefore, for example, it is difficult to make the filament body compact by simply reducing the length of the tungsten wire.

  Therefore, in a halogen bulb having a rated voltage of 100 [V] or higher, a double-wound coil is generally used in order to make the filament body compact. Patent Document 1 discloses a halogen light bulb using a triple wound coil as a filament body for further compaction. According to this, if the length of the tungsten wire is the same, the length of the entire coil in the optical axis direction of the reflecting mirror can be shortened, thereby improving the light collection efficiency.

However, as the number of coil turns increases, the vibration amplitude of the coil generated when an external force (impact force) is applied to the halogen bulb increases, which causes a problem that the wire is easily disconnected.
As a halogen bulb capable of reducing the size of the filament body (shortening in the optical axis direction) while solving this problem, Patent Document 2 discloses that three or four single coils are entirely disposed on the optical axis of the reflecting mirror. There is disclosed a structure in which each single coil is arranged in parallel to the optical axis of a reflecting mirror so as to be symmetrical with respect to the mirror. As a result, the length in the optical axis direction is shortened as compared with the case where a single or single coil corresponding to three or four single coils is produced, thereby improving the light collection efficiency. Become. Moreover, since each coil is single, the problem caused by the vibration is reduced.

Furthermore, Patent Document 3 discloses a halogen light bulb having a structure in which a filament body is composed of 4 to 6 single coils, and one of them is arranged at a position including the optical axis of the reflecting mirror. Yes. This is because it is generally considered that there is a large difference in the illuminance obtained when the coil (that is, the light emitting unit) is present at the optical axis position.
However, configuring a filament body with three or more single coils complicates the support structure that electrically connects the coils and supports each coil, and that the coil can be assembled to the support structure. It becomes difficult and not realistic.

Therefore, the inventors of the present application configure the filament body with two single coils, and each single coil is formed by winding an element wire in a flat cylindrical shape (hereinafter referred to as “flat coil”). .) Was created. That is, the filament body is configured to emit light in an energized state at two places that are wound in a flat shape.
According to this, as compared with a conventional single coil (hereinafter referred to as “cylindrical coil”) formed by winding an element wire in a cylindrical shape, the short axis length of the flat tube is equal to the diameter of the cylinder. If the wire length of the tungsten wire is the same, the coil length can be shortened because the wire length per turn can be increased. As a result, the filament body can be shortened in the optical axis direction, which is equivalent to the case where the filament body is composed of three or more cylindrical coils. Here, each of the two places that emit light in an energized state is referred to as a “light emitting portion”.

In consideration of symmetry with respect to the optical axis of the reflecting mirror, the two light emitting portions (flat coils) are arranged at positions that are symmetrical with respect to the optical axis.
JP 2001-345077 A Japanese National Patent Publication No. 6-510881 JP 2002-63869 A

  However, when a halogen bulb equipped with a filament body having the above-described configuration having two light emitting portions is incorporated in a reflecting mirror and used as spotlight illumination, the center portion of the spotlight on the irradiation surface becomes dark and the surroundings become brighter. It turned out to be a so-called donut-like spot shape. That is, it was found that the bimodality in which the peak appears at two places appears in the light distribution curve. Further, it was recognized that this tendency becomes more prominent as the beam opening in the reflecting mirror becomes narrower. It goes without saying that such a spot shape is not preferable as spot illumination for literally rising an object.

  In view of the above-described problems, the present invention eliminates the bimodality in the light distribution curve and darkens the central portion while adopting a simple configuration in which the filament body is configured by two light emitting portions having a flat coil shape. An object of the present invention is to provide a tube that can obtain a spotlight that does not become necessary. Another object of the present invention is to provide a reflector-equipped tube having such a tube and an illumination device.

  In order to achieve the above object, a tube according to the present invention is a tube that is used by being incorporated in a reflecting mirror having a concave reflecting surface. The filament body is configured to emit light in an energized state at two locations that are wound in a flat shape, with one light emitting portion serving as the first light emitting portion and the other light emitting portion serving as the second light emitting portion. In the case of the light emitting part, the first light emitting part and the second light emitting part are arranged so that the distance of the light emitting center of the first light emitting part from the central axis of the bulb is different from the distance of the light emitting center of the second light emitting part. It is characterized by.

Further, the first and second light emitting units are arranged in a posture in which each coil axis is substantially parallel to the central axis.
Further, the first light emitting unit has a coil axis substantially parallel to the central axis, and the second light emitting unit is arranged in a posture in which the coil axis is inclined with respect to the central axis. To do.
Further, the first light emitting unit and the second light emitting unit are arranged in such a direction that the ends of the light emitting units on the light irradiation opening side of the reflecting mirror approach each other from the posture in which the coil axis is parallel to the central axis. It is arranged in an inclined state.

Further, the first light emitting unit and the second light emitting unit are arranged so that the ends of the light emitting units opposite to the light irradiation opening of the reflecting mirror are in an attitude in which the coil axis is parallel to the central axis. It is characterized by being arranged in a tilted direction.
In addition, the filament body is configured by bending a filament coil in which a filament wire is flattened and wound at a substantially central portion in the longitudinal direction, and is formed between the bent portion and one end of the filament coil. The second light emitting unit exists while one light emitting unit reaches the other end.

Furthermore, one of the first light emitting part and the second light emitting part is arranged at a position including the central axis.
In order to achieve the above object, a tube with a reflecting mirror according to the present invention includes a reflecting mirror and the above-described tube incorporated in the reflecting mirror.
In order to achieve the above object, an illuminating device according to the present invention includes a luminaire having a reflecting mirror, and the above-described tube incorporated in the reflecting mirror.

  In order to achieve the above object, an illuminating device according to the present invention includes a luminaire and the above-described bulb with a reflector attached to the luminaire.

  According to the tube having the above configuration, the influence of the influence on the shape of the light distribution curve of the light emitting unit related to the light emitting center closer to the central axis of the bulb is the light distribution of the light emitting unit related to the light emitting center far from the central axis. As a result of being dominant over the influence on the shape of the curve, the bimodality in the light distribution curve is eliminated, and a spotlight whose center is not dark is obtained.

Hereinafter, embodiments of the present invention will be described with reference to the drawings.
FIG. 1 is a partially cutaway view showing a schematic configuration of lighting apparatus 10 according to Embodiment 1. FIG. In all the drawings including FIG. 1, the scales between the members are not unified.
The illumination device 10 is used as spotlight illumination in, for example, a house, a store, or a studio. The lighting device 10 includes a lighting fixture 12 and a halogen bulb 14 shown as an example of a tube.

The lighting fixture 12 includes a bottomed cylindrical tool body 16 and a reflecting mirror 18 housed in the tool body 16.
A receiver (not shown) for attaching a base 30 (see FIG. 2) of the halogen light bulb 14 is provided at the bottom of the instrument body 16. Note that the instrument body 16 is not limited to a cylindrical shape, and may have various known shapes.

The reflecting mirror 18 can be attached to and detached from the instrument body 16 so that the halogen bulb 14 can be replaced.
The reflecting mirror 18 has a hard glass substrate 20 having a funnel shape. A multilayer interference film 22 constituting a reflection surface is formed on a concave surface portion 20A formed on a spheroidal surface or a paraboloid of the substrate 20. The multilayer interference film 22 can be formed of silicon dioxide (SiO ₂ ), titanium dioxide (TiO ₂ ), magnesium fluoride (MgF), zinc sulfide (ZnS), or the like, in addition to a metal film such as aluminum or chromium. The aperture diameter (mirror diameter) of the reflecting mirror 18 is 100 mm, and the beam opening (beam angle) is narrow (about 10 °). In addition, you may form a facet in a reflective surface as needed.

The reflecting mirror 18 has a front glass 24 provided in an opening (light irradiation opening) of the base 20. In this example, the front glass 24 is fixed to the base 20, and the base 20 is configured to be detachable from the instrument body 16 for replacement of the halogen light bulb 14. However, the present invention is not limited to this. The front glass may be fixed to the main body and the front glass may be detachable from the base.
The halogen light bulb 14 is attached to the receiver (not shown) and incorporated in the reflecting mirror 18 for use. In the assembled (attached) state, a central axis B of a bulb 26 described later of the halogen bulb 14 is positioned substantially coaxially with an optical axis R of the reflecting mirror 18 (central axis B and optical axis R). Is approximately the same). The halogen light bulb 14 is a light bulb having a rated voltage of 100 [V] or more and 150 [V] or less and a rated power of 100 [W] or less.

FIG. 2 shows a partially cutaway front view of the halogen bulb 14.
The halogen light bulb 14 includes a bulb 26 that is hermetically sealed, and an E-type base 30 that is fixed to the sealing portion 38 side of the bulb 26 with an adhesive 28.
The valve 26 is formed by a tip-off portion 32 that is a residual mark of sealing cut, a filament body housing portion 34 that houses a filament body 60 and the like to be described later, a substantially cylindrical tube portion 36, and a known pinch seal method. The sealing portions 38 are connected in this order.

  As shown in FIG. 2, the filament body storage portion 34 has a substantially spheroid shape. The "substantially spheroid shape" mentioned here means not only including a complete spheroid shape, but also including a shape deviated from the complete spheroid shape by the amount of variation in processing of the glass. Yes. The filament body storage portion is not limited to the shape described above, and may be, for example, a substantially cylindrical shape, a substantially spherical shape, or a substantially complex ellipsoidal shape.

Further, the structure of the valve is not limited to the one described above, and for example, a tip-off part (which may not be provided in some cases), a filament body housing part, and a sealing part may be connected in this order.
An infrared reflecting film is formed on the outer surface of the filament body storage portion 34. However, this infrared reflective film is not necessarily required, and is appropriately formed.

A predetermined amount of halogen substance and rare gas are sealed in the bulb 26. In addition to this, nitrogen gas may be sealed.
The halogen substance is for returning tungsten, which is a constituent material evaporated from the filament body 60 to the filament body 60 again by the halogen cycle during lighting, and preventing the bulb 26 from being blackened. The concentration of the halogen substance is preferably in the range of 10 [ppm] to 300 [ppm]. In order to activate the halogen cycle, the coldest spot temperature on the inner surface of the bulb 26 is preferably 200 [° C.] or higher. Furthermore, in order for the halogen cycle to function properly, the oxygen concentration in the bulb 26 is preferably set to 100 [ppm] or less.

As the rare gas, krypton gas is preferably used. By using krypton gas, in order to make the filament body compact for the purpose of increasing the light collection efficiency, the light emitting units are arranged close to each other as described later, but at any place between adjacent light emitting units. It is possible to obtain an effect of suppressing the occurrence of arc discharge during lighting and disconnection.
In particular, the filled gas contains nitrogen gas and a halogen substance mainly composed of krypton, and the gas pressure in the bulb 26 at normal temperature may be set within a range of 2 [atm] to 10 [atm]. preferable. If the gas pressure exceeds 10 [atm], in the unlikely event that the bulb 26 is damaged, the lighting fixture may be damaged by scattered pieces. On the other hand, if the gas pressure is less than 2 [atm], the filament body 60 This is because tungsten, which is a constituent material, easily evaporates and the lamp life is shortened. In other words, since the gas pressure is moderately suppressed in the above range, even if the bulb 26 is damaged, the fragments are not scattered at such a moment that the lighting fixture is damaged, and Since the gas pressure is moderately high, tungsten, which is a constituent material of the filament body 60, is difficult to evaporate, and it is possible to realize a long life. Further, arc discharge occurs at any place between adjacent light emitting parts during lighting. And it is the range which can suppress disconnecting.

  Moreover, when nitrogen gas is included in the sealed gas, the composition ratio of the nitrogen gas is preferably set in the range of 8 [%] to 40 [%]. If the composition ratio of nitrogen gas exceeds 40 [%], the heat generated in the filament body 60 during lighting is excessively released through the nitrogen gas, and the efficiency may be reduced. On the other hand, less than 8 [%] This is because arc discharge is likely to occur between adjacent light emitting portions during lighting, and disconnection is likely to occur. In other words, since the composition ratio of nitrogen gas is moderately suppressed, the composition ratio range of nitrogen gas is efficient because heat generated in the filament body 60 during lighting is excessively released through the nitrogen gas. In this range, it is possible to prevent the occurrence of arc discharge and to prevent disconnection due to arc discharge occurring in the adjacent light emitting section tube during lighting because nitrogen gas is appropriately contained.

A pair of metal foils 40 and 42 are sealed in the sealing portion 38. The metal foils 40 and 42 are made of molybdenum. In addition, in order to prevent the airtightness of the valve 26 from being impaired due to overheating of the metal foils 40 and 42 sealed to the sealing portion 38, the surface of the sealing portion 38 is made uneven. It is preferable to increase the surface area and improve the heat dissipation at the sealing portion 38.
One end portion of the external lead wire 44 is joined to one end portion of the metal foil 40, and one end portion of the external lead wire 46 is joined and electrically connected to one end portion of the metal foil 42. The external lead wires 44 and 46 are made of tungsten. The other end portions of the external lead wires 44 and 46 are led out of the valve 26 and are electrically connected to the terminal portions 48 and 50 of the base 30, respectively.

  Here, a fuse (not shown) is provided between at least one of the two external lead wires 44 and 46 and the corresponding terminal portion (48 or 50) of the base 30. Is preferred. By providing the fuse, even if a break occurs in the light emitting part and an arc discharge occurs at the disconnection point, the fuse is immediately blown and the continuation of the arc discharge is stopped, and the arc discharge is interrupted. 26 can be prevented from being damaged. In particular, when a plurality of light emitting portions are arranged close to each other, it is preferable to provide a fuse between each of the external lead wires 44 and 46 and the corresponding terminal portions 48 and 50 of the base 30. In this case, there is a possibility that arc discharge may occur between adjacent light emitting units even if arc discharge due to disconnection in the light emitting unit does not occur.

  One end portion of the internal lead wire 52 is joined to the other end portion of the metal foil 40, and one end portion of the internal lead wire 54 is joined and electrically connected to the other end portion of the metal foil 42. The internal lead wires 52 and 54 are made of tungsten. One end portions of the internal lead wires 52 and 54 are supported by the sealing portion 38 of the valve 26. The internal lead wires 52 and 54 supply external power supplied via the base 30 to the filament body 60 and serve as a support member that directly supports a part of the filament body 60.

3 is a perspective view showing a support structure that supports the filament body 60, and FIG. 4 is a perspective view showing a state in which the filament body 60 is supported by the support structure.
As shown in FIG. 3, as a support member that directly supports a part of the filament body 60, there is a support wire 56 made of tungsten.
The internal lead wires 52 and 54 and the support wire 56 are sandwiched between a pair of cylindrical stem glasses 57 and 59. As a result, the support wire 56 is supported and the relative positions of the internal lead wires 52 and 54 and the support wire 56 are maintained.

As shown in FIG. 4, the filament body 60 includes two filament coils, a first filament coil 62 and a second filament coil 64. The first and second filament coils 62 and 64 are obtained by winding a tungsten wire as will be described later.
The internal lead wires 52 and 54 and the support wire 56 are inserted into end portions of the filament coils 62 and 64 and bent into a “U” shape for supporting the filament coils 62 and 64 (hereinafter, this portion). Is referred to as “coil support”).

Here, the first filament coil 62 is supported by a coil support portion 52A (see FIG. 3) of the internal lead wire 52 and a coil support portion 56A (see FIG. 3) of the support wire 56.
The second filament coil 64 is supported by a coil support portion 56B (see FIG. 3) of the support wire 56 and a coil support portion 54A (see FIG. 3) of the internal lead wire 54.
As is clear from FIG. 4, one end portions of the first filament coil 62 and the second filament coil 64 are electrically connected by a support wire 56. That is, the first filament coil 62 and the second filament coil 64 are connected in series by the support line 56 that functions as a conductive connecting member.

  In the state shown in FIG. 4, when power is supplied from the internal lead wires 52 and 54 (that is, in the energized state), the first and second filament coils 62 and 64 do not emit light at the portion where the coil support portion is inserted. (Non-light emitting part), light is emitted between coil support parts. Here, the portions between the coil support portions (that is, the portions that emit light) in the filament coils 62 and 64 are defined as the first light emitting portion 62A and the second light emitting portion 64A, respectively. That is, the filament body 60 has two light-emitting portions 62A and 64A having a single coil shape.

  Further, as shown in FIG. 4, the first and second filament coils 62 and 64 (first and second light emitting portions 62A and 64A) are wound in a flat cylindrical shape (hereinafter referred to as “flat”). Abbreviated as “coil”). The reason for this shape is as follows. That is, as compared with a conventional single coil wound in a cylindrical shape (hereinafter referred to as “cylindrical coil”) as described in Patent Document 2 and Patent Document 3, (flat tube) (If the short axis length of the cylinder is equal to the diameter of the cylinder) The wire length per turn can be increased. If the strand length of the tungsten wire is the same, the coil length can be shortened. This is because the filament coil (light emitting portion) in the optical axis direction (bulb central axis) of the reflecting mirror can be reduced. By flattening the coil, the length in the direction intersecting the optical axis of the reflecting mirror is longer than that of the coil wound in a cylindrical shape, but in order to improve the light collection efficiency, it intersects with the optical axis. There is no problem because the effect of shortening in the direction of the optical axis is greater than the direction in which it is performed.

The filament coils 62 and 64 which are flat coils are produced as follows.
That is, as shown in FIG. 5, after winding a tungsten wire 68 around the outer periphery of a plurality of cylindrical core wires (mandrels) 66 (four in the illustrated example) arranged in parallel and in close contact with each other. The core wire 66 is melted and produced.
The upper part of FIG. 6 schematically shows a plan view of the first filament coil 62 viewed from the coil axis CX direction, and the lower part of FIG. 6 schematically shows the front view. It is a representation.

Since the first and second filament coils 62 and 64 have substantially the same shape, the first filament coil 62 will be described as a representative.
As shown in the upper part of FIG. 6, the first filament coil 62 has a so-called semicircle formed by connecting corresponding ends of two line segments arranged in parallel when viewed from the coil axis CX direction. It has a track shape (for track and field). This shape is derived from the above-described manufacturing method, and the flatter track shape is obtained as the number of the core wires 66 is increased. That is, the degree of flatness (flatness) can be adjusted by the number of core wires 66.

Here, the flatness is defined as a value obtained by dividing the length of the long axis LX in the inner periphery of the first filament coil 62 by the length of the short axis SX. In this example, the flatness is an integer value because of the above manufacturing method, and the flatness is 4 as an example.
Further, as described above, as shown in the lower part of FIG. 6, the first filament coil 62 includes the non-light emitting part 62B at both end parts supported by the coil support part 52A and the coil support part 56A (FIGS. 3 and 4). And a light emitting part 62A between the coil support parts 52A and 56A. Here, the “light emission center” of the filament coil is defined. If the first filament coil 62 is defined as an example, the “light emission center 62CP” is on the coil axis CX and is the middle position in the entire length L of the light emitting portion 62A. An example of the specification of the first filament coil 62 is summarized as follows.

Long axis LX length (long inner diameter): 1.4 mm
Short axis CX length (short inner diameter): 0.35 mm
Light emitting part total length L (effective coil length): 4.5 mm
Wire (tungsten wire) diameter: 0.05mm
In addition, the light emission part full length L is not restricted to said value, It can set in the range of 2.5 mm-6.5 mm. This range can be applied to the entire length of the light emitting portion in all the filament bodies described later.

  The upper part of FIG. 7 shows the first and second filament coils 62 and 64 attached to the internal lead wires 52 and 54 and the support wire 56 with the central axis B of the bulb 26 (FIGS. 1 and 2). A plan view seen from the direction is schematically shown, and the lower part of FIG. 7 schematically shows the front view. 7 can be said to be a view of the first and second filament coils 62 and 64 seen from the direction of the optical axis R (FIG. 1) of the reflecting mirror 18 when the halogen bulb 14 is incorporated in the reflecting mirror 18. . Here, since FIG. 7 is used for the purpose of explaining the relationship of the arrangement position between the first and second filament coils 62 and 64, the illustration of the internal lead wires 52 and 54 is omitted in this figure, and the support line is omitted. 56 is simply represented by a line for the purpose of showing an electrical connection relationship between the first and second filament coils 62 and 64. In the lower front view, the first and second light emitting portions 62A and 64A of the first and second filament coils 62 and 64 are represented by solid lines, and the non-light emitting portions 62B and 64B are represented by two-dot chain lines.

  As shown in FIG. 7, the first filament coil 62 (first light emitting unit 62A) and the second filament coil 64 (second light emitting unit 64A) are: (i) each coil axis CX is substantially the same as the central axis B; They are parallel, and (ii) both coil axes and the central axis B are on substantially the same plane, and (iii) both long axes LX are substantially parallel to each other, and are provided with an interval D1. Here, the coil interval D1 is set to 0.9 mm as an example.

  Further, the distance D2 of the first filament coil 62 (first light emitting part 62A) from the central axis B is different from the distance D3 of the second filament coil 64 (second light emitting part). That is, the distance of the light emission center CP of the first light emitting unit 62A from the central axis B is different from the distance of the light emission center CP of the second light emitting unit 64A. In this example, D2 = 0.15 mm and D3 = 0.75 mm. Here, regarding D1, D2 and D3, a halogen bulb provided with the filament body set to the above-mentioned value is referred to as “first embodiment bulb”.

  Here, the coil interval D1 is set to 0.9 mm as in the first embodiment bulb, and for D2 and D3, a halogen bulb having a filament body in which D2 = D3 = 0.45 mm is set as “first comparison” “Light bulb”. That is, the first comparative light bulb has a filament body in which two filament coils (light emitting portions) are arranged symmetrically with respect to the central axis B, and is referred to in [Problems to be solved by the invention]. Such a light bulb has a problem in light distribution characteristics.

  Regarding the first example bulb and the first comparative bulb, the light distribution characteristics when these were combined with a reflecting mirror were investigated. The survey was conducted under the following conditions. The halogen bulb attached to a commercially available halogen bulb with a reflector (manufactured by Matsushita Electric Industrial Co., Ltd., product number JDR110V65WKN / 5E11) was replaced with the first comparison bulb or the bulb of the first example. The halogen light bulb with a reflector has a narrow beam opening (beam angle) of about 10 °. When each of the two halogen bulbs with reflectors thus made was lit at a rated voltage of 110 [V] and a rated power of 65 [W], it was separated from the halogen bulb with the reflectors by a distance of 1 [m]. The light distribution characteristics (light distribution curve) on the irradiated surface were investigated. In addition, since the light distribution characteristics of the comparative light bulb, which will be described later other than the first comparative light bulb and the first embodiment light bulb, and the light bulb characteristics of the example light bulb were also investigated in the same manner as described above, the description of each condition and the like will be omitted. I will do it.

The survey results are shown in FIG. In FIG. 9, those relating to the first comparative light bulb are indicated by broken lines, and those relating to the first embodiment light bulb are indicated by alternate long and short dash lines.
Looking at the first comparative light bulb, a bimodality in which the peaks of the light distribution curve appear in two places is recognized. That is, as already described, the center portion is dark and the surroundings are bright spotlights.

  On the other hand, in the first embodiment bulb, the bimodality is eliminated and the peak of the light distribution curve is single. That is, it is a spotlight having a good light distribution characteristic that is substantially symmetrical with the brightest part as the center. This is because the light distribution curve of the first light-emitting portion 62A related to the light emission center 62CP closer to the central axis B is made different from the distance between the light emission center 62CP (FIG. 7) and the light emission center 64CP from the central axis B. This is considered to be because the influence on the shape of the light emission becomes more dominant than the influence on the shape of the light distribution curve of the second light emitting portion 64A related to the light emission center 64CP far from the central axis B.

  FIG. 8 shows a filament body 70 in which the first filament coil 62 (first light emitting portion 62A) is further brought closer to the central axis B and the second filament coil 64 (second light emitting portion 64A) is further moved away from the central axis B. It is. In the filament body 70, the first filament coil 62 (first light emitting unit 62A) is arranged at a position including the central axis B. In the filament body 70, the coil interval D4 is set to 0.9 mm. The halogen light bulb provided with the filament body 70 was referred to as “second embodiment light bulb”, and the light distribution characteristics related to this were investigated.

The survey result is shown by a solid line in FIG.
As shown by the solid line in FIG. 9, according to the second embodiment light bulb, the above-mentioned bimodality is eliminated and the maximum illuminance value is larger than that of the first embodiment light bulb. However, the left-right symmetry with respect to the peak is slightly impaired. Even in a halogen bulb (hereinafter referred to as “third embodiment bulb”) having a coil interval D4 set to 2 mm, the light distribution is the same as that of the second embodiment bulb as shown by the light distribution curve shown by the solid line in FIG. It became a characteristic.

  Therefore, in order to improve the asymmetry of the light distribution curve, the second filament coil 64 (second light emitting portion 64A) is inclined with respect to the central axis B. FIG. 10 shows such a filament body 72. From the state shown in FIG. 8, the filament body 72 maintains the distance between the one end portions of the first light emitting portion 62A and the second light emitting portion 64A (D4 = D5 = 2 mm) and the end of the second light emitting portion 64A. The angle α = 20 ° with respect to the corner of the part. A light distribution curve of a halogen light bulb including the filament body 72 (hereinafter referred to as “fourth embodiment light bulb”) is shown by a one-dot chain line in FIG. In this way, by tilting the second filament coil 64 (second light emitting portion 64A) far from the central axis B, the light distribution curve becomes substantially symmetrical with respect to the peak, and the light distribution characteristics are improved. I understand that.

In the light bulb of the fourth embodiment (FIG. 10), only one filament coil is inclined with respect to the central axis B, but both filament coils may be inclined with respect to the central axis B. FIG. 12 is a view showing the filament body 74 configured as described above.
The filament body 74 maintains the distance D6 (= 2 mm) between the one end portions of the first light emitting portion 62A and the second light emitting portion 64A, and the corners of the end portions of the first light emitting portion 62A and the second light emitting portion 64A. The angle β = γ = 7 ° with respect to the part. In other words, the filament body 74 is configured so that the first light emitting unit 62A and the second light emitting unit 64A are arranged in the light emitting units 62A, 64A from the posture shown in FIG. 7 with the coil axis CX parallel to the central axis B. These are arranged in a state where the end portions of the reflecting mirror 18 on the light irradiation opening side are inclined toward each other. In this example, both the first light emitting unit 62A and the second light emitting unit 64A are inclined by the same angle (β = γ = 7 °), but the inclination angles β and γ may be different. Needless to say, the tilt angle is not limited to 7 °.

Also in this example, the light emission center 62CP of the first light emitting unit 62A is closer to the central axis B than the light emission center 64CP of the second light emitting unit 64A. Incidentally, the distance D7 shown in FIG. 12 is 0.4 mm, and the distance D8 is 1.6 mm.
Here, the halogen light bulb including the filament body 74 configured as described above is referred to as a “fifth embodiment light bulb”. In FIG. 12, a halogen body including a filament body in which D7 = D8 = 1 mm, that is, a filament body in which the first light-emitting portion 62A and the second light-emitting portion 64A are arranged so as to be symmetric with respect to the central axis B. The light distribution curve of the fifth example light bulb and the second comparative light bulb is shown in FIG.

  In FIG. 13, the light distribution curve of the second comparative bulb is indicated by a broken line, and the light distribution curve of the fifth embodiment bulb is indicated by a solid line. From FIG. 13, even when both the first and second light emitting units 62A and 64A are inclined with respect to the central axis B, the light distribution curve is bimodal when arranged symmetrically with respect to the central axis B. It can be seen that a light distribution curve in which bimodality is eliminated can be obtained by differentiating the distances from the light R axis of both emission centers.

In the filament body 74 (FIG. 12) according to the light bulb of the fifth embodiment, the first light emitting part 62A and the second light emitting part 64A are inclined while maintaining linearity. The state in which the ends on the light irradiation opening side of the mirror are tilted toward each other also includes a state in which each light emitting part is bent inwardly (toward the opposite counterpart light emitting part). It is a waste.
Further, the light emitting portions 62A and 64A may be tilted in the opposite direction to the filament body 74 (FIG. 12) according to the fifth embodiment bulb. FIG. 14 is a view showing the filament body 76 configured as described above. That is, the filament body 76 is configured so that the first light emitting unit 62A and the second light emitting unit 64A are disposed between the light emitting units 62A and 64A from the posture as shown in FIG. The reflecting mirror 18 is arranged in a state where the ends opposite to the light irradiation opening are inclined toward each other.
(Embodiment 2)
In the halogen light bulb of the first embodiment, the filament body is constituted by two filament coils in which one end portions are electrically connected by a support wire. And since a part of each filament coil will light-emit in the energized state to a halogen light bulb, the filament body has two light emission locations.

  On the other hand, in the second embodiment, one filament coil is bent at a substantially central portion in the longitudinal direction (coil axis direction), and between the bent portion including the non-light emitting portion and one end portion of the filament coil. The second light emitting unit is present while the first light emitting unit reaches the other end. The halogen light bulb according to the second embodiment includes the halogen substance, the rare gas and the like enclosed in the bulb, except for the filament body and the support structure thereof, in the first embodiment (including each example). The configuration is basically the same as that of the halogen bulb. Therefore, the following description will focus on the different parts. Needless to say, the lighting apparatus can be configured by mounting the halogen light bulb of the second embodiment on the lighting fixture 12 (FIG. 1) of the first embodiment.

FIG. 15 is a perspective view showing a schematic configuration of the filament body 202 and its support structure according to the first example of the halogen light bulb of the second embodiment.
The filament body 202 is formed by bending one filament coil 204 made in the same manner as the filament coils 62 and 64 (FIGS. 4 and 6) (FIG. 5) at the center and holding it in a bent state. is there. That is, like the filament coils 62 and 64, the filament coil 204 is a single coil in which a filament wire is wound in a cylindrical shape having a flat cross section having a short axis and a long axis. The filament coil 204 is bent in the minor axis direction starting from the center.

One end portion of the filament coil 204 is supported by the coil support portion 206A of the internal lead wire 206, and the other end portion is supported by the coil support portion 208A of the internal lead wire 208. Reference numerals 212 and 214 denote stem glass.
And the longitudinal direction center part (bending part) of the filament coil 204 is suspended and supported by the support wire 210 which is a support member. The filament coil 204 does not emit light at the portions supported by the coil support portions 206A and 208A (non-light emitting portion) as in the case of the first embodiment. The internal lead wires 206 and 208 and the support wire 210 are made of tungsten.

  16 shows a plan view of the filament coil 204 attached to the internal lead wires 206 and 208 and the support wire 210 when viewed from the direction of the central axis B (FIGS. 1 and 2) of the bulb 26. FIG. This is a schematic representation, and what is shown in the lower part of FIG. 16 is a schematic representation of the front view, which is drawn in the same manner as in FIG. In the figure shown in the lower part of FIG. 16, the support wire 210 is represented by a cut end surface cut at a portion where the filament coil 204 is directly suspended. In FIG. 16, the light emitting portions (204A1, 204A2) in the filament coil 204 are represented by solid lines and the non-light emitting portions (204C) are represented by two-dot chain lines in both the upper plan view and the lower front view.

Since the filament coil 204 is bent as described above, its coil axis is similarly bent in the same plane. The filament coil 204 is arranged such that its coil axis is substantially on the same plane as the central axis B.
Further, in the bent portion of the filament coil 204, several turns (several turns) supported by and in contact with the conductive support wire 210 are electrically short-circuited, and thus do not emit light even in an energized state. The range where light is not emitted depends on the form of the bent portion, the degree of bending (bending angle), the shape of the support line, and the like, but at least a part of the bent portion becomes a non-light emitting portion. That is, in the filament body 204, the first light emitting portion 204A1 exists between the bent portion including the non-light emitting portion and one end portion of the filament coil 204, and the second light emitting portion 204A2 exists between the other end portion.

  Unlike the case of the first embodiment, the support line 210 does not need a function of electrically connecting the filament coils and only needs to be able to mechanically support the filament coils. It is also possible to form it with a material. Even in this case, since the coil pitch becomes narrower as the adjacent windings (turns) contact each other inside the bent portion of the filament coil 204, the coil pitch becomes narrower and a short circuit occurs at the contact portion. Arise. As a result, the short circuit portion does not emit light.

  Needless to say, also in the filament body 202 according to the first example of the second embodiment, the distance D10 of the first light emitting unit 204A1 from the central axis B is different from the distance D11 of the second light emitting unit 204A2. By making the distance of the light emission center 204CP1 of the first light emitting part 204A1 from the central axis B different from the distance of the light emission center 204CP2 of the second light emitting part 204A2, the bimodality in the light distribution curve is eliminated, and the central part A spotlight that is not darker than its surroundings can be obtained.

  In the filament body 202 according to the first example, the central axis B between the first light emitting unit 204A1 and the second light emitting unit 204A2 is similar to the filament body 74 (FIG. 12) according to the fifth example of the first embodiment. The interval in the orthogonal direction becomes narrower as it gets closer to the light irradiation opening side of the reflecting mirror 18 (in other words, it gets wider as it gets farther from the light irradiation opening of the reflecting mirror 18), as shown in FIG. As described above, the first light-emitting portion 204A1 and the second light-emitting portion 204A are formed in a “C” shape, but on the contrary, as in the filament body 76 (FIG. 14) of the first embodiment, You may make it make a "C" shape.

  FIG. 17 shows the filament body 220 according to the second example of the second embodiment configured as described above. FIG. 17 schematically shows a front view of the filament body 220, which is drawn in the same manner as the lower figure of FIG. The filament body 220 (FIG. 17) has the same configuration as the filament body 202 (FIG. 16) except that the opening directions of the first light-emitting portion 204A1 and the second light-emitting portion 204A2 are different. Accordingly, in the filament body 220 shown in FIG. 17, the same reference numerals are given to substantially the same components as the filament body 202, and the description thereof is omitted. The support wire 222 that supports the filament body 220 and internal lead wires (not shown) can be realized by appropriately bending a tungsten wire.

Further, in the filament body 202 (FIGS. 15 and 16) and the filament body 220 (FIG. 17), both the first light emitting unit 204A1 and the second light emitting unit 204A2 are inclined with respect to the central axis B. Not limited to this, only one light emitting portion may be inclined with respect to the central axis B, and the other light emitting portion may be configured to be substantially parallel to the central axis B.
Furthermore, in the filament body 202 (FIGS. 15 and 16) and the filament body 220 (FIG. 17), both the light-emitting portions (204A1, 204A1, and the like) are arranged so that one light-emitting portion (first light-emitting portion 204A1) includes the central axis B. 204A2) is provided, but the present invention is not limited to this, and the light emitting units may be arranged in such a positional relationship that the central axis B exists between the light emitting units 204A1 and 204A2. Of course, even in this case, the first light emitting unit 204A1 and the first light emitting unit 204A1 are different from the first light emitting unit 204A1 so that the distance from the central axis B of the light emitting center 204CP1 of the first light emitting unit 204A1 is different from the distance of the light emitting center 204CP2 of the second light emitting unit 204A2. Two light emitting units 204A2 are arranged.
(Embodiment 3)
FIG. 18 is a longitudinal sectional view showing a schematic configuration of a halogen lamp 100 with a reflector according to the third embodiment.

  The halogen bulb 100 with a reflector is a reflector-integrated halogen bulb, but the halogen bulb 102 used therein is different from the halogen bulb 14 (FIG. 2) according to Embodiment 1 except that the base is mainly different. Since the configuration is basically the same, common portions are denoted by the same reference numerals, and description thereof is omitted. Needless to say, the filament body of the halogen light bulb constituting the halogen light bulb with a reflecting mirror may be the one according to the second embodiment.

The reflecting mirror 104 is made of hard glass or quartz glass and has a funnel-shaped base 106. On the concave surface portion 106A formed on the spheroidal surface or the paraboloid of the base 106, a multilayer interference film 108 constituting a reflective surface is formed. The multilayer interference film 108 can be formed of silicon dioxide (SiO ₂ ), titanium dioxide (TiO ₂ ), magnesium fluoride (MgF), zinc sulfide (ZnS), or the like, in addition to a metal film such as aluminum or chromium. The opening diameter (mirror diameter) of the reflecting mirror 104 is 100 mm. In addition, you may form a facet in a reflective surface as needed.

  The reflecting mirror 104 has a front glass 110 provided in an opening (light irradiation opening) of the base 106. The front glass 110 is locked to the base 106 by a known stopper 112. In addition, it may replace with the fastener 112 and may adhere with an adhesive. Or you may use both together. However, the front glass is not an essential component of the halogen light bulb with a reflector, and may be omitted.

  The neck portion 106 </ b> B of the base body 106 is fitted with a base body receiving portion 122 provided on the side opposite to the terminal portions 116 and 118 of the base 114 of the halogen light bulb 102, and is fixed by an adhesive 124. Prior to the attachment of the base 106 to the base 114, the valve 26 is attached to the base 114. Needless to say, with the bulb 26 and the base 106 (reflecting mirror 104) attached to the base 114 (that is, with the halogen bulb 102 incorporated in the reflecting mirror 104), the central axis of the bulb 26 is The optical axis of the reflecting mirror 104 is positioned substantially on the same axis (the central axis and the optical axis substantially coincide).

As mentioned above, although this invention has been demonstrated based on embodiment, this invention is not restricted to an above-described form, Of course, it can also be set as the following forms, for example.
(1) In the first embodiment, the lighting device is configured by the lighting fixture including the reflecting mirror and the halogen light bulb. However, the lighting device is not limited thereto, and the lighting device does not include the reflecting mirror and the halogen light bulb with the reflecting mirror. It does not matter even if it constitutes. Specifically, for example, instead of the reflector 18 and the halogen bulb 14 in the illumination device shown in FIG. 1, the halogen bulb 100 with a reflector shown in FIG. 18 may be attached to constitute the illumination device.
(2) The filament coil is not limited to the track shape described above, and may have another flat shape. In short, it may be wound in a cylindrical shape having a flat cross section having a major axis and a minor axis perpendicular to each other. Further, the flatness is not limited to an integer, and can be an arbitrary decimal number.

Here, in the present invention, the “flat cross section having a short axis and a long axis” includes the following shapes. The shape will be described with reference to FIG. In FIG. 19, the symbol “SX” is assigned to the short axis, the symbol “LX” is assigned to the major axis, and the central axis (that is, the coil axis) substantially orthogonal to both the minor axis and the major axis “ "CX" is attached respectively.
(I) As shown in FIG. 5A, when viewed from the coil axis CX direction, the above-described track shape, that is, two parallel line segments and their respective ends connected by a substantially semicircle. .

(Ii) As shown in FIG. 5B, when the circular shape is crushed when viewed from the coil axis CX direction.
(Iii) As shown in the figure (c), it is substantially elliptical when viewed from the coil axis CX direction. (Iv) As shown in the figure (d), it is substantially as seen from the coil axis CX direction. A rectangular one. However, the four corners are rounded for processing.

(V) Other than the coil axis CX direction, a shape similar to the above (i) to (iv). For example, in (i) above, as shown in (e) in the figure, even if two parallel line segments are curved inward, they are included in a shape similar to (i) above. In addition, here, the deformed shapes (i) to (iv) described above due to processing variations are also included.
(3) The values shown for the distances (D1, D4, D5, D6, D9, D12) related to the coil (light emitting section) of the above embodiment are merely examples, and other values are set in the range of 0.2 mm to 4 mm. Can do.
(4) In the above embodiment, a halogen bulb is shown as an example of a tube, but the present invention can also be applied to a tube other than a halogen bulb. In short, any light source that emits incandescent light by passing an electric current through the filament body may be used.

  The tube according to the present invention can be suitably used as, for example, a tube used by being incorporated in a reflecting mirror.

1 is a partially cutaway view illustrating a schematic configuration of a lighting device according to Embodiment 1. FIG. It is a figure which shows the halogen light bulb which comprises the said illuminating device. It is a perspective view which shows the support structure of the filament body in the said halogen bulb. It is a perspective view which shows the state by which the filament body was supported by the said support structure. It is a figure for demonstrating the manufacturing method of the filament coil which comprises the said filament body. It is a schematic diagram showing the top view (upper part) and front view (lower part) of a filament coil. It is the schematic diagram which represented an example of the filament body in Embodiment 1 with the top view (upper part) and the front view (lower part). It is the schematic diagram which represented an example of the filament body in Embodiment 1 with the top view (upper part) and the front view (lower part). It is a figure showing a light distribution curve. It is the schematic diagram which represented an example of the filament body in Embodiment 1 with the top view (upper part) and the front view (lower part). It is a figure showing a light distribution curve. It is the schematic diagram which represented an example of the filament body in Embodiment 1 with the top view (upper part) and the front view (lower part). It is a figure showing a light distribution curve. It is the schematic diagram which represented an example of the filament body in Embodiment 1 with the top view (upper part) and the front view (lower part). It is a perspective view which shows schematic structure of an example of the filament body in Embodiment 2, and its support structure. It is the schematic diagram showing an example of the filament body in Embodiment 2 with the top view (upper part) and the front view (lower part). It is the schematic diagram showing an example of the filament body in Embodiment 2 with the top view (upper part) and the front view (lower part). It is a figure which shows schematic structure of the halogen light bulb with a reflector which concerns on Embodiment 3. FIG. It is the figure which illustrated the shape of the cross section of a flat cylinder (shape).

Explanation of symbols

DESCRIPTION OF SYMBOLS 10 Lighting apparatus 12 Lighting fixture 14,102 Halogen light bulb 18,104 Reflector 26 Valve 60,70,72,74,76,202,220 Filament body 62,64,204 Filament coil 62A, 64A, 204A1,204A2 Light emission part 62CP , 64CP, 204CP1,204CP2 Luminous center 100 Halogen bulb with reflector

Claims (10)

A tube used by being incorporated in a reflecting mirror having a concave reflecting surface,
A hermetically sealed valve and a filament body provided in the valve;
When the filament body is configured to emit light in an energized state in two places that are wound in a flat shape, when one light emitting part is a first light emitting part and the other light emitting part is a second light emitting part,
The first light emitting part and the second light emitting part are arranged so that the distance of the light emitting center of the first light emitting part from the central axis of the bulb is different from the distance of the light emitting center of the second light emitting part. Tube to play.   2. The tube according to claim 1, wherein the first and second light emitting units are arranged in a posture in which each coil axis is substantially parallel to the central axis.   The first light emitting unit has a coil axis that is substantially parallel to the central axis, and the second light emitting unit is arranged such that the coil axis is inclined with respect to the central axis. Item 1. A tube according to item 1.   The first light-emitting part and the second light-emitting part are tilted so that the ends of the light-emitting aperture side of the reflecting mirrors of both light-emitting parts approach each other from a posture in which the coil axis is parallel to the central axis. The tube according to claim 1, wherein the tube is arranged in a state.   The first light-emitting part and the second light-emitting part are oriented so that the ends of the light-emitting parts opposite to the light irradiation opening of the reflecting mirrors approach each other from a posture in which the coil axis is parallel to the central axis. The tube according to claim 1, wherein the tube is arranged in a tilted state. The filament body is configured by bending a filament coil in which a filament wire is flattened into a single flat shape and bending it at a substantially central portion in the longitudinal direction,
The tube according to claim 1, wherein the first light emitting portion exists between the bent portion and one end of the filament coil, and the second light emitting portion exists between the other end.   One of a 1st light emission part and a 2nd light emission part is distribute | arranged to the position containing the said central axis, The tube of any one of Claims 1-6 characterized by the above-mentioned. A reflector,
The tube according to any one of claims 1 to 7, which is incorporated in the reflecting mirror;
A tube with a reflector, characterized by comprising: A lighting fixture having a reflector;
The tube according to any one of claims 1 to 7, which is incorporated in the reflecting mirror;
A lighting device comprising: Lighting equipment,
The bulb with a reflector according to claim 8 attached to the lighting fixture;
A lighting device comprising:

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