JP2010198878A - Electrodeless fluorescent lamp, and luminaire using the same - Google Patents

Abstract

An electrodeless fluorescent lamp capable of suppressing a decrease in luminous efficiency due to a temperature rise during lighting is provided.
A valve 2 comprising at least an outer shell part 3 made of a light-transmitting material and gas-tightly sealed inside, and a concave part 4 falling into the inner side of the outer shell part 3; An induction coil 23 housed in the recess 4 to excite the gas into a discharge gas in the discharge space, and a light emitting layer that emits light by being excited by ultraviolet rays emitted from the discharge gas on the inner surface of the bulb 2. And at least part of the light emitting layer has a higher temperature at which temperature quenching occurs from the surface side of the bulb 2 to the discharge gas side. Are formed in order.
[Selection] Figure 1

Description

  The present invention relates to an electrodeless fluorescent lamp and a lighting fixture using the same.

  Conventionally, as an example of an electrodeless fluorescent lamp, a bulb having at least an outer shell portion made of a light-transmitting material such as glass and hermetically sealed with a gas and a recessed portion that falls inside the outer shell portion. An excitation coil housed in the recess for exciting the gas into a discharge gas in the discharge space of the bulb, and ultraviolet light emitted from the discharge gas on the inner surface of the bulb. A light emitting layer that emits light is known.

  In this electrodeless fluorescent lamp, an induction electromagnetic field is generated in the discharge space in the bulb by flowing a high-frequency current through the induction coil, and the gas enclosed in the bulb is excited by the induction electromagnetic field. It becomes the discharge gas. Here, when a rare gas and mercury vapor are used as the gas, the rare gas discharges and excites the mercury vapor. The excited mercury vapor emits ultraviolet rays when returning from the excited state to the ground state. The ultraviolet light hits the phosphor of the light emitting layer and is converted in wavelength, and visible light is emitted from the phosphor of the light emitting layer.

  This type of electrodeless fluorescent lamp is a general fluorescent lamp in which a filament is arranged in an airtight container made of a translucent material (hereinafter referred to as an electroded fluorescent lamp in order to distinguish it from an electrodeless fluorescent lamp). In principle, non-lighting due to filament breakage does not occur, and the service life can be extended.

  However, the electrodeless fluorescent lamp is considered to be susceptible to the deterioration of the phosphor due to a chemical reaction of mercury with the phosphor due to collision of excited mercury and mercury ions caused by discharge with the phosphor of the light emitting layer. Yes. In particular, in the configuration of the electrodeless fluorescent lamp described above, since the induction coil to be energized is housed in the recess, an electric field is concentrated on the side where the induction coil is close in the discharge space when the lamp is turned on. Of the inner surface of the bulb, the light emitting layer formed on the surface of the recess is more likely to deteriorate than the light emitting layer formed on the surface of the outer shell.

By the way, when forming an electrodeless fluorescent lamp in which white light having high color rendering properties is emitted by using a so-called rare earth three-wavelength phosphor for the phosphor of the light emitting layer, the phosphor includes, for example, blue Barium magnesium aluminate [Ba ₂ Mg ₂ Al ₁₆ O ₂₇ : Eu ²⁺ ] (hereinafter referred to as BAM phosphor) activated by divalent europium as a blue phosphor that emits light of As a green phosphor that emits red, lanthanum phosphate [LaPO ₄ : Ce, Tb] activated by trivalent cerium and terbium (hereinafter referred to as a LAP phosphor) is used as a red phosphor that emits red light. , trivalent yttrium oxide activated by europium _[Y 2 _O 3: ^{Eu 3+]} (hereinafter, referred to as YOX phosphors) can be used three By mixing these phosphors and binding them with a binder, the light emitting layer of the inorganic fluorescent lamp can be formed.

  However, the three types of phosphors used in the light emitting layer have different deterioration characteristics. Although it depends on the composition, the BAM phosphor emitting blue light is particularly deteriorated. From such a viewpoint, it is desirable that a BAM phosphor that is originally deteriorated is not used as much as possible in the light emitting layer formed on the surface of the recess.

  From such a viewpoint, as shown in FIG. 6, an outer shell portion 3 made of a light-transmitting material and filled with a gas serving as a discharge gas is provided, and a concave portion 4 that falls down inside the outer shell portion 3 is provided. A light emitting layer 6 ′ having a phosphor formed on the inner surface of the bulb 2 ′, and an induction coil 23 wound around the outer periphery of the ferrite core 22 and housed in the recess 4. A light emitting layer 6 ′ provided on the inner side of the bulb 2 ′ in the concave portion 4 and the first light emitting layer 6 ′ b in the outer shell portion 3. There has been proposed an electrodeless fluorescent lamp 1 ′ composed of a second light emitting layer 6′a and having a structure in which a phosphor (for example, BAM phosphor) having the greatest deterioration is not used for the second light emitting layer 6′a. (For example, Patent Document 1).

  Thereby, the BAM phosphor with the greatest deterioration with time of the electrodeless fluorescent lamp 1 ′ is excluded from the light emitting layer 6 ′ on the inner side of the bulb 2 ′ in the recess 4 where the deterioration is relatively likely to occur, so that the electrodeless fluorescence is eliminated. It is possible to suppress the color change due to the deterioration of the lamp 1 ′ over time. In FIG. 6, the induction coil 23 is configured to be electrically connected to the power supply unit 34 ′ via the power supply wires 11 and 12 housed in the housing 13.

Japanese Patent No. 2887410

  However, in the electrodeless fluorescent lamp 1 ′, only the deterioration of the light emitting layer 6 ′ due to plasma discharge is focused. For example, in the electrodeless fluorescent lamp 1 ′, the induction coil 23 may be disposed as close as possible to the surface of the recess 4 in the bulb 2 ′ in order to efficiently apply an induction electromagnetic field to the discharge space inside the bulb 2 ′. This is effective, and the surface of the recess 4 close to the induction coil 23 tends to become high as the induction coil 23 rises in temperature. It is considered that this is because the induction coil 23 is housed in the recess 4 and the heat dissipation of the recess 4 is deteriorated.

  Further, the closer the induction electromagnetic field generated by the induction coil 23 is to the induction coil 23, the stronger the electromagnetic field is, and the plasma of the discharge gas generated inside the bulb 2 ′ is in the vicinity of the recess 4 near the induction coil 23. It tends to concentrate and become hot. In particular, the induction coil 23 side of the concave portion 4 can be radiated from the discharge gas side of the concave portion 4 although heat can be removed through a heat radiating pipe (not shown) disposed inside the ferrite core 22. Is difficult.

  As a result, the concave portion 4 of the electrodeless fluorescent lamp 1 ′ becomes very hot compared with the region where the light emitting layer of a normal electroded lamp is formed, and a part of the concave portion 4 exceeds 150 ° C. to 200 ° C. It may become such a temperature. When the temperature of the phosphor in the light emitting layer rises while the electrodeless fluorescent lamp 1 ′ is turned on, temperature quenching that reduces the luminance of the phosphor occurs, and the luminous efficiency of the electrodeless fluorescent lamp 1 ′ decreases. There is a problem. Therefore, the configuration of Patent Document 1 cannot suppress a decrease in efficiency due to temperature quenching.

  The present invention has been made in view of the above-described reasons, and provides an electrodeless fluorescent lamp capable of suppressing a decrease in light emission efficiency due to a temperature rise during lighting and a lighting fixture using the same.

  The invention of claim 1 comprises a bulb comprising at least an outer shell portion made of a light-transmitting material and gas-tightly sealed therein, and a concave portion that falls inside the outer shell portion, and a discharge space of the bulb. An inductive coil housed in the recess for exciting the gas into a discharge gas, and a light emitting layer that emits light by being excited by ultraviolet rays emitted from the discharge gas on the inner surface of the bulb. An electrodeless fluorescent lamp, wherein at least a part of the light emitting layer is composed of two or more phosphor films, and has a higher temperature at which temperature quenching occurs from the surface side of the bulb to the discharge gas side. It is characterized by having a multilayer structure with body coatings in order.

  According to this invention, at least a part of the light emitting layer is composed of two or more layers of the phosphor coating, and the temperature at which temperature quenching is higher from the surface side of the bulb to the discharge gas side is higher. By adopting a multilayer structure with a coating in order, the luminous efficiency of the electrodeless fluorescent lamp is reduced due to the temperature quenching of the phosphor (a phenomenon in which the luminescence efficiency of the phosphor decreases as the temperature of the phosphor increases). Can be suppressed.

  According to a second aspect of the present invention, in the first aspect of the invention, the light emitting layer of the multilayer structure is inside the bulb, the surface of the concave portion facing the induction coil side, and the discharge space. And provided on the surface of the outer shell portion facing the induction coil side.

  According to the present invention, the light emitting layer has a specific multilayer structure only in specific portions of the outer shell portion and the concave portion of the bulb that are exposed to a high temperature by a discharge gas during operation of the electrodeless fluorescent lamp. A decrease in the luminous efficiency of the electrode fluorescent lamp can be prevented.

  According to a third aspect of the present invention, in the first aspect of the invention, the light emitting layer having the multilayer structure is provided inside the bulb and on the surface of the concave portion.

  According to the present invention, it is possible to prevent the luminous efficiency of the electrodeless fluorescent lamp from being lowered only by making the light emitting layer in the concave portion of the bulb have the specific multilayer structure. In addition, since the area of the light emitting layer of the multilayer structure is small, it can be easily formed, and color unevenness can be suppressed from occurring in the light emitted from the electrodeless fluorescent lamp.

  According to a fourth aspect of the present invention, in the first aspect of the invention, the light emitting layer of the multilayer structure is inside the bulb, and the outer shell portion facing the induction coil side through the discharge space. It is provided on the surface.

  According to this invention, during the lighting of the electrodeless fluorescent lamp, the light emitting layer on the surface of the outer shell portion facing the induction coil side through the discharge space has a specific multilayer structure. , It is possible to prevent a decrease in luminous efficiency of the electrodeless fluorescent lamp. Moreover, since the area of the light emitting layer of the multilayer structure is small, it can be easily formed, and the influence of color unevenness of light emitted from the electrodeless fluorescent lamp can be reduced.

  According to a fifth aspect of the present invention, in the invention according to any one of the first to fourth aspects, the light-emitting layer having the multilayer structure has a phosphor film in which temperature quenching occurs at the lowest temperature and the highest temperature. It is characterized in that a heat insulating layer is provided between the phosphor film which hardly causes temperature quenching.

  According to this invention, by providing the heat insulating layer, it is possible to further suppress the temperature rise of the phosphor coating that causes temperature quenching at the lowest temperature, and to reduce the decrease in the luminous efficiency of the electrodeless fluorescent lamp. Can do.

  The invention according to claim 6 is the invention according to any one of claims 1 to 5, wherein the light emitting layer of the multilayer structure is a trivalent from the surface side of the bulb to the discharge gas side. A first phosphor coating having lanthanum phosphate activated by cerium and terbium; a second phosphor coating having barium magnesium aluminate activated by divalent europium; and trivalent europium. And a third phosphor film having activated yttrium oxide.

  According to the present invention, the luminous efficiency of yttrium oxide activated by trivalent europium in the third phosphor coating is improved, and activated by trivalent cerium and terbium in the first phosphor coating. Thus, the temperature quenching of the lanthanum phosphate can be reduced, and the electrodeless fluorescent lamp in which the decrease in luminous efficiency is further suppressed can be obtained.

  Invention of Claim 7 is a lighting fixture provided with the electrodeless fluorescent lamp of any one of Claim 1 thru | or 6, and the lighting device which lights this electrodeless fluorescent lamp, To do.

  According to this invention, it can be set as a lighting fixture with higher energy efficiency by setting it as the lighting fixture provided with the electrodeless fluorescent lamp which can suppress the fall of the luminous efficiency accompanying the temperature rise during lighting.

  According to the first aspect of the present invention, at least a part of the light emitting layer is composed of two or more phosphor films, and the phosphor film having a higher temperature at which temperature quenching occurs is provided in order from the surface side of the bulb to the discharge gas side. The electrodeless fluorescent lamp having a light emitting layer having a multilayer structure has an effect of suppressing a decrease in luminous efficiency of the electrodeless fluorescent lamp due to temperature quenching of the phosphor.

  In invention of Claim 7, it is more preferable by setting it as the lighting fixture provided with the electrodeless fluorescent lamp of any one of Claim 1 thru | or 6, and the lighting device which makes this electrodeless fluorescent lamp light. There exists an effect that it can be set as a lighting fixture with high energy efficiency.

The electrodeless fluorescent lamp of Embodiment 1 is shown, (a) is a principal part schematic sectional drawing, (b) is a schematic sectional drawing. 6 is a schematic cross-sectional view of an electrodeless fluorescent lamp according to Embodiment 2. FIG. It is a schematic sectional drawing of the electrodeless fluorescent lamp of Embodiment 3. It is a principal part schematic sectional drawing of the electrodeless fluorescent lamp of Embodiment 4. It is a schematic perspective view of the lighting fixture of Embodiment 5. It is a schematic sectional drawing of the conventional electrodeless fluorescent lamp.

(Embodiment 1)
Hereinafter, the electrodeless fluorescent lamp of this embodiment will be described with reference to FIG.

  The electrodeless fluorescent lamp 1 of the present embodiment has at least an outer shell 3 made of a light-transmitting material and hermetically sealed with gas as shown in FIG. 1B, and falls inside the outer shell 3. A bulb 2 having a recessed recess 4; an induction coil 23 housed in the recess 4 for exciting the gas into a discharge gas in the discharge space of the bulb 2; and the inner side of the bulb 2 A light emitting layer that is excited by ultraviolet rays emitted from the discharge gas and emits light.

  At least a part of the light emitting layer is a light emitting layer 6 having a multilayer structure as shown in FIG. 1A, and the temperature at which temperature quenching occurs from the surface side of the bulb 2 to the discharge gas side is higher. A first phosphor film 61 having a LAP phosphor, a second phosphor film 62 having a BAM phosphor, and a third phosphor film 63 having a YOX phosphor are sequentially provided.

  Hereafter, each structure of this embodiment is explained in full detail.

  As a basic configuration of the present embodiment, an electrodeless fluorescent lamp 1 includes a bulb 2 formed of a translucent material (glass or the like), a lamp portion 10 constituted by a substantially cylindrical base 9 attached to the bottom of the bulb 2, And a power coupler unit 20 having an induction coil 23 that generates an induction electromagnetic field in the bulb 2 when a high-frequency current is applied, and coupled to the lamp unit 10.

  The bulb 2 constituting the lamp portion 10 has a light bulb shape as a whole, and includes an outer shell portion 3, a concave portion 4 that is recessed inside the outer shell portion 3, and a bottom surface in the concave portion 4 in the concave portion 4. And a gas such as a rare gas (such as argon or krypton) or mercury vapor is sealed inside. Further, a protective film (not shown) made of a metal oxide such as alumina is formed on the inner surface of the bulb 2, and ultraviolet rays emitted from mercury excited as a light emitting layer are visible on the protective film. A phosphor film in which a phosphor for conversion into light is fixed by a binder is formed. The protective film can be suitably provided to prevent the glass component of the bulb 2 from eluting to the inside of the bulb 2 and to prevent a decrease in light transmittance due to a chemical reaction between the glass component and mercury.

  The outer shell 3 is a main light emitting part, and a spherical part 3a and a cylindrical part 3b are continuously formed. A locking groove 3c for fixing the base 9 is formed on the outer periphery of the cylindrical portion 3b.

  The concave portion 4 is formed in a cylindrical shape in which the flange portion 4a of the concave portion 4 and the cylindrical portion 3b of the outer shell portion 3 are welded and dropped from the end of the cylindrical portion 3b to the inside of the outer shell portion 3, A bottom surface is formed at the bottom of the recess.

  The tubular portion 5 is formed in a cylindrical shape that is thinner than the cylinder of the recess 4, and one end in the axial direction is erected at the center of the bottom surface in the recess 4, and the internal space is the inner side of the outer shell 3. And the discharge space enclosed by the outside of the recess 4. The tubular portion 5 is formed by using an exhaust pipe for exhausting the inside of the valve 2, and the other end is drawn out of the recess 4, and the inside of the valve 2 is evacuated to gas such as argon gas. Is introduced, the container 8 in which the amalgam is stored in the tubular portion 5 is accommodated, the other end portion of the tubular portion 5 is sealed, and the valve 2 is hermetically sealed.

  Further, on the inner wall of the tubular portion 5, a projecting portion 5 a projecting inward is formed on the one end side having the opening of the tubular portion 5, and the container 8 is placed in the projecting portion 5 a and the tubular portion 5. It is held by a cylindrical rod 7 arranged. The protrusion 5a is preferably provided at a substantially central position in the bulb 2 inside the induction coil 23 described later as a position where the temperature of the bulb 2 is relatively high.

  The container 8 containing the amalgam is a container 8 made of a metal material (for example, FeNi alloy) formed in a hollow cylindrical container shape, and a particulate amalgam that supplies mercury vapor into the discharge space inside the container 8. Is stored. Amalgam is obtained by adding mercury to a base metal made of an alloy of bismuth and indium, for example. By using this amalgam containing mercury, the mercury vapor pressure in the bulb 2 can be kept substantially constant over a wide temperature range as compared with the case where mercury alone is used. In addition, mercury vapor can enter and leave the outer peripheral wall of the container 8 in the longitudinal direction, and a plurality of holes that can prevent amalgam from falling off are provided (not shown).

  The base 9 constituting the lamp portion 10 is formed in a cylindrical shape whose both ends are opened by a resin material or the like, and an engagement protrusion 9 a protruding inward is provided on the inner peripheral surface. It is locked in the locking groove 3c.

  On the other hand, the power coupler portion 20 described above includes a cylindrical heat radiating pipe 21 formed of a heat conductive material such as Al or Cu and into which the tubular portion 5 of the lamp portion 10 is inserted, and one end portion of the heat radiating pipe 21 in the axial direction. The cylindrical cylinder 24 with the side inserted, the outer radiating portion 25 that supports the cylindrical radiating pipe 21 and the cylindrical cylinder 24, and the other end portion side of the radiating pipe 21 are covered with the radiating pipe 21. A ferrite core 22 and an induction coil 23 wound around the ferrite core 22 are provided. In this power coupler portion 20, most of the cylinder 24, most of the heat radiating pipe 21, the ferrite core 22, and the induction coil 23 are accommodated in the recess 4 of the lamp portion 10, and the induction coil 23 extends along the axial direction of the tubular portion 5. It is wound around.

  Here, as the ferrite core 22, for example, MnZn ferrite having a Curie temperature of 250 ° C. or higher and a saturation magnetic flux density of 0.5 T or higher is preferably used so as to maintain a stable impedance without being saturated even at a high temperature. it can.

  Next, the light emitting layer in the electrodeless fluorescent lamp 1 of this embodiment will be described in detail.

  Many of the light emitting layers of the present embodiment are mixed with three kinds of phosphors (YOX phosphor, LAP phosphor, BAM phosphor) described later, and the outer shell 3 and the recess 4 of the bulb 2 are mixed. Although formed on the surface (not shown), at least a part of the light emitting layer is formed without forming a phosphor film using a plurality of types of mixed phosphors as shown in FIG. It is formed on the light emitting layer 6 having a specific multilayer structure.

  That is, as described above, the electrodeless fluorescent lamp 1 has a very high temperature at a specific part of the bulb. For example, when high frequency power of 150 W is applied to the electrodeless fluorescent lamp 1, a substantially central portion where the induction coil 23 is disposed in the concave portion 4 of the bulb 2, a portion near the base 9 of the concave portion 4, and an outer shell portion of the bulb 2. The surface temperature of the maximum diameter portion in 3 is shown in the following table.

  As can be seen from this table, the temperature of the substantially central portion where the induction coil 23 is disposed in the recess 4 is 214 ° C., the temperature in the vicinity of the base 9 in the recess 4 is 72 ° C., and the maximum in the outer shell portion 3. The diameter is higher than the temperature of 105 ° C.

  The light-emitting layer 6 having a multilayer structure according to the present embodiment has a plurality of phosphor films 61, 62, 63 laminated with different types of phosphors covered with a binder, and discharge gas is discharged from the surface side of the bulb 2. On the side, phosphor films 61, 62, 63 having higher temperatures at which temperature quenching occurs are provided in this order.

In order to make the electrodeless fluorescent lamp 1 capable of emitting white light using the phosphors used for the phosphor coatings 61, 62, and 63, for example, a blue phosphor material that emits blue light is divalent. A BAM phosphor can be used as barium magnesium aluminate [Ba ₂ Mg ₂ Al ₁₆ O ₂₇ : Eu ²⁺ ] activated by europium. In addition, as a material for a green phosphor that emits green light, a LaP phosphor can be used as lanthanum phosphate [LaPO ₄ : Ce, Tb] activated by trivalent cerium and terbium. As a material of the red phosphor that emits red light, a YOX phosphor can be used as yttrium oxide [Y ₂ O ₃ : Eu ³⁺ ] activated by trivalent europium.

  In a three-wavelength fluorescent lamp using such red, green, and blue phosphor materials, the LAP phosphor has a significantly reduced luminous efficiency (temperature quenching) at a high temperature of 200 ° C. or higher, and the YOX phosphor. Is higher in temperature at which temperature quenching occurs than BAM phosphors and LAP phosphors, and tends to have high luminous efficiency on the high temperature side.

  In the present embodiment, the light emitting layer 6 having a specific multilayer structure is inside the bulb 2, the surface of the recess 4 facing the induction coil 23 side, and the outer shell facing the induction coil 23 side through the discharge space. It is provided on the surface of the part 3. More specifically, as shown in FIG. 1 (a), the first fluorescence having a green phosphor composed of a LAP phosphor, in which the temperature at which temperature quenching occurs becomes higher from the surface side of the bulb 2 to the discharge gas side. A body film 61, a second phosphor film 62 having a blue phosphor made of BAM phosphor, and a third phosphor film 63 having a red phosphor made of YOX phosphor are sequentially provided. As a result, the first phosphor film 61 having the LAP phosphor that is more susceptible to temperature quenching on the surface side of the bulb 2 than the second phosphor film 62 having the BAM phosphor, and the discharge gas side have a higher temperature. An electrodeless fluorescent lamp which has a multilayered light-emitting layer 6 to be a third phosphor film 63 having a YOX phosphor that is difficult to quench, thereby preventing the temperature quenching of the LAP phosphor and improving the luminous efficiency of the YOX phosphor Can be 1.

(Embodiment 2)
The basic configuration of the electrodeless fluorescent lamp 1 of the present embodiment is substantially the same as that of the first embodiment, and a light emitting layer 6 having a specific multilayer structure as shown in FIG. The difference is that it is not provided on the surface of the outer shell portion 3 facing the induction coil 23 side via the discharge space. In addition, the same code | symbol is attached | subjected to the component similar to Embodiment 1, and description is abbreviate | omitted suitably.

  In the electrodeless fluorescent lamp 1 shown in the first embodiment, green light, blue light, and red light emitted from the three phosphor films 61, 62, and 63 are mixed as the light emitting layer 6 having a multilayer structure. Although it is possible to obtain mixed color light such as white, and this can suppress a decrease in luminous efficiency, each phosphor coating 61, 62, 63 is formed on the outer shell 3 having a large surface area in the bulb 2 with a uniform film thickness. It is difficult to form a multilayer structure.

  In the electrodeless fluorescent lamp 1 of the present embodiment, the light emitting layer of the outer shell 3 of the bulb 2 forms a light emitting layer by mixing and coating three red phosphors, green phosphors and blue phosphors. The light emitting layer 6 having a specific multilayer structure is formed only on the surface side facing the induction coil 23 side in the recess 4 having a smaller surface area than the shell 3. Thereby, the light emitting layer 6 of a specific multilayer structure can be formed with a comparatively uniform film thickness, and the fall of the light emission efficiency accompanying temperature quenching can be suppressed.

(Embodiment 3)
The basic configuration of the electrodeless fluorescent lamp 1 of the present embodiment is substantially the same as that of the second embodiment, and a light emitting layer 6 having a specific multilayer structure as shown in FIG. The difference is that it is provided on the entire surface of the side wall of the recess 4 from that provided only on the surface facing the induction coil 23 side. In addition, the same code | symbol is attached | subjected to the component similar to Embodiment 2, and description is abbreviate | omitted suitably.

  In the present embodiment, only the light emitting layer on the surface of the recess 4 has a multilayer structure.

  In order to form the light emitting layer 6 having a specific multilayer structure in the recess 4, the material to be the recess 4 is immersed in a slurry solution containing a phosphor in the binder. Therefore, it is difficult to form the light emitting layer 6 having a multilayer structure only in a part as in the second embodiment, and the phosphor coatings 61, 62, and 63 have a uniform film thickness relatively easily by applying the entire recess 4 to the multilayer. A light emitting layer 6 having a multilayer structure can be formed. In addition, it is possible to form the light emitting layer 6 having a specific multilayer structure not only on the side wall of the recess 4 but also on the bottom surface more easily.

  Further, the phosphors used for the phosphor coatings 61, 62, 63 are mixed and separately formed on the surface of the outer shell 3.

  Next, the flange portion 4a of the concave portion 4 in which the light emitting layer 6 having a multilayer structure is formed is welded to the cylindrical portion 3b of the outer shell portion 3, so that the outer shell portion 3 is removed from the end of the cylindrical portion 3b. It can be set as the shape of the valve | bulb 2 formed in the cylindrical shape which fell inside and was depressed.

  By using such a bulb 2, the electrodeless fluorescent lamp 1 of the present embodiment can suppress a decrease in light emission efficiency due to temperature quenching with a relatively simple configuration.

(Embodiment 4)
Since the basic configuration of the electrodeless fluorescent lamp 1 of this embodiment is the same as that of the first to third embodiments, the characteristic portions will be described with reference to FIG. In addition, the same code | symbol is attached | subjected to the component similar to Embodiment 1-3, and description is abbreviate | omitted suitably.

  In the electrodeless fluorescent lamp 1 of this embodiment, the light emitting layer 6 having a specific multilayer structure has a first phosphor film 61 in which temperature quenching occurs at the lowest temperature, and a third that hardly causes temperature quenching to the highest temperature. By providing the heat insulating layer 15 between the phosphor film 63 and the phosphor film 63, the first phosphor film 61 in which temperature quenching occurs at the lowest temperature can be maintained at a lower temperature.

More specifically, as shown in FIG. 4, the first phosphor film 61 having a green phosphor made of LAP phosphor, in which the temperature at which temperature quenching occurs from the surface side of the bulb 2 to the discharge gas side becomes higher. A second phosphor film 62 having a blue phosphor made of BAM phosphor and a third phosphor film 63 having a red phosphor made of YOX phosphor in order, and the third most difficult to cause temperature quenching The heat insulating layer 15 is provided on the surface side of the bulb 2 in the phosphor coating 63. Thereby, it is possible to suppress the temperature increase of the first phosphor film 61 at which the temperature at which the temperature quenching occurs is lowest, and to prevent the light emission efficiency from being lowered due to the temperature quenching. As a material for the heat insulating layer 15, it is possible to use silica (SiO ₂₎ and titania (TiO ₂₎ metal oxides such as.

(Embodiment 5)
The lighting fixture of this embodiment comprises the lighting fixture 30 using the electrodeless fluorescent lamp 1 described in Embodiment 1-4 as shown in FIG. In addition, the same code | symbol is attached | subjected to the component similar to each embodiment, and description is abbreviate | omitted suitably.

  This lighting fixture 30 accommodates the electrodeless fluorescent lamp 1 described in Embodiments 1 to 4 inside, and has a bowl shape that efficiently reflects the light emitted from the electrodeless fluorescent lamp 1 to the light extraction surface side. The reflection plate 31 and a front panel 32 provided on the light extraction surface side of the reflection plate 31 are hermetically sealed. In addition, the electrodeless fluorescent lamp 1 is a power supply unit serving as a lighting device capable of driving the induction coil 23 of the electrodeless fluorescent lamp 1 with power from a commercial power source (not shown) in order to light the electrodeless fluorescent lamp 1. It is electrically connected via 34.

  In such a lighting fixture 30, due to a rise in the ambient temperature of the electrodeless fluorescent lamp 1 inside the lighting fixture 30 due to long-time lighting of the electrodeless fluorescent lamp 1, the inside of the electrodeless fluorescent lamp 1. Temperature tends to rise. However, the electrodeless fluorescent lamp 1 using Embodiments 1 to 4 is caused by temperature quenching because the light emitting layer 6 has a specific multilayer structure even if the ambient temperature of the electrodeless fluorescent lamp 1 is increased. It can be set as the lighting fixture 30 which can suppress that luminous efficiency falls.

DESCRIPTION OF SYMBOLS 1 Electrodeless fluorescent lamp 2 Bulb 3 Outer shell part 4 Recessed part 5 Tubular part 6 Light emitting layer 15 Heat insulation layer 25 Induction coil 30 Lighting fixture 61 1st fluorescent substance film 62 2nd fluorescent substance film 63 3rd fluorescent substance film

Claims (7)

A bulb comprising at least an outer shell portion made of a light-transmitting material and having a gas hermetically sealed therein, and a concave portion recessed inside the outer shell portion; and exciting the gas in the discharge space of the bulb An electrodeless fluorescent lamp having an induction coil housed in the recess for forming a discharge gas, and a light emitting layer that emits light by being excited by ultraviolet rays emitted from the discharge gas on the inner surface of the bulb. And
At least a part of the light emitting layer is composed of two or more layers of phosphor coatings, and has a multilayer structure sequentially including phosphor coatings having higher temperatures at which temperature quenching occurs from the surface side to the discharge gas side of the bulb. An electrodeless fluorescent lamp characterized by being.   The light emitting layer of the multilayer structure is the inside of the bulb, the surface of the concave portion facing the induction coil side, and the outer shell portion of the outer shell portion facing the induction coil side through the discharge space. The electrodeless fluorescent lamp according to claim 1, wherein the electrodeless fluorescent lamp is provided on a surface.   2. The electrodeless fluorescent lamp according to claim 1, wherein the light emitting layer having the multilayer structure is provided inside the bulb and on the surface of the recess.   The light emitting layer having the multilayer structure is provided on the surface of the outer shell portion facing the induction coil side through the discharge space inside the bulb. The electrodeless fluorescent lamp described.   The light-emitting layer having the multilayer structure is characterized in that a heat insulating layer is provided between a phosphor film in which temperature quenching occurs at the lowest temperature and a phosphor film that hardly causes temperature quenching to the highest temperature. The electrodeless fluorescent lamp according to any one of claims 1 to 4.   The light emitting layer of the multilayer structure includes a first phosphor film having lanthanum phosphate activated by trivalent cerium and terbium from the surface side to the discharge gas side of the bulb, and divalent europium. And a third phosphor film having yttrium oxide activated by trivalent europium and a second phosphor film having barium magnesium aluminate activated by The electrodeless fluorescent lamp according to any one of claims 1 to 5.   An illumination fixture comprising: the electrodeless fluorescent lamp according to any one of claims 1 to 6; and a lighting device that lights the electrodeless fluorescent lamp.

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