JP2006221928A - High-pressure discharge lamp - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a mercury-free high-pressure discharge lamp which is intended to improve electrical and lamp characteristics. <P>SOLUTION: The high-pressure discharge lamp is provided with an airtight container 1 composed of transparent ceramics which have a discharge space inside and contain no silicon (Si) as a component element, a pair of electrodes 2 which are sealed inside the airtight container 1 and face a discharge space 1c, and an ionization medium sealed inside the airtight container 1. This ionization medium contains thulium (Tm) halides with a maximum sealing ratio, aluminum (Al) or aluminum halides, and noble gas, but is essentially mercury-free. <P>COPYRIGHT: (C)2006,JPO&NCIPI

Description

  The present invention relates to a high-pressure discharge lamp essentially free of mercury.

In order to make mercury-free high-pressure discharge lamps such as metal halide lamps, it is necessary to use a buffer substance instead of mercury. It is known to those skilled in the art that the following conditions are required as conditions that can be a buffer substance.
(1) High vapor pressure.
(2) Large cross-sectional area of collision with electrons.
(3) High ionization potential and excitation energy.

  Substances satisfying the above conditions include magnesium (Mg), iron (Fe), cobalt (Co), chromium (Cr), zinc (Zn), nickel (Ni), manganese (Mn), aluminum (Al), Examples include antimony (Sb), bismuth (Bi), beryllium (Be), rhenium (Re), gallium (Ga), titanium (Ti), zirconium (Zr), and hafnium (Hf). Among these metals, aluminum (Al) is expected to be preferable because it does not contribute to visible light emission.

However, when the hermetic container is made of quartz glass, it reacts vigorously between silicon oxide (SiO ₂ ) and aluminum (Al) or its halide, and the white turbidity of the hermetic container due to the production of aluminum oxide (Al ₂ O ₃ ). And cracks occur. Further, as a result of the above reaction, a low melting point alloy is generated between the dissociated silicon (Si) and the electrode material tungsten (W), resulting in a short lamp life due to electrode dissolution and a low luminous flux maintenance factor.

Therefore, the hermetic vessel is changed to quartz glass and formed of, for example, translucent alumina containing at least aluminum (Al) as a component element, and aluminum halide is enclosed as a lamp voltage forming medium in place of mercury in the hermetic vessel. A metal halide lamp has been proposed (see Patent Document 1). According to the metal halide lamp described in Patent Document 1, a desired high lamp voltage can be obtained as a so-called mercury-free metal halide lamp, and the airtight container does not cause white turbidity due to the aluminum halide. Therefore, the lamp short life and the low luminous flux maintenance factor due to electrode melting accompanying the generation of a low melting point alloy between silicon (Si) and tungsten (W) are not caused.
Japanese Patent Laid-Open No. 11-040102

  However, according to the example of the metal halide lamp described in Patent Document 1, the luminous efficiency is 53.4 to 62.7 lm / W, and has not yet reached a practical value. Moreover, although it is described that the lamp voltage fluctuation during the lifetime is suppressed with respect to the lamp voltage, it is a discussion on relative values, and it is not clear whether an appropriate lamp voltage is obtained as an absolute value.

  The present inventor studied improvement of the metal halide lamp described in Patent Document 1. As a result, the appropriate lamp voltage increases almost in proportion to the amount of aluminum halide enclosed, but the luminous efficiency is not necessarily proportional. In addition, when the amount of aluminum halide enclosed is increased, the ratio of the main luminescent substance halide contained is relatively reduced, and the luminous efficiency is thus reduced. Furthermore, if the total enclosed amount of the entire ionization medium increases, the luminous efficiency decreases, the probability of an increase in impure gas adhering to the ionization medium and flowing into the discharge space increases, or the liquid phase remains without being evaporated. Thus, it has been found that the ionization medium adhering to the inner surface of the hermetic container has problems such as a decrease in light emission efficiency, a decrease in life characteristics and an increase in manufacturing cost due to light shielding by discharge.

  The present inventor has found that it is effective to eliminate a factor that leads to a decrease in lamp voltage in order to avoid the above-described problem, and has reached the present invention.

  An object of the present invention is to provide a mercury-free high-pressure discharge lamp with improved electrical characteristics and lamp characteristics.

    The high-pressure discharge lamp of the present invention includes a hermetic container made of a translucent ceramic having a discharge space therein and containing no silicon (Si) as a component element; a pair of electrodes sealed in the hermetic container and facing the discharge space; An ionization medium containing a maximum enclosure ratio of thulium (Tm) halide, aluminum (Al) or aluminum halide and a rare gas, and essentially enclosed in an airtight container without mercury. It is characterized by.

[Regarding the Airtight Container] The airtight container is made of a translucent ceramic that does not contain silicon (Si) as a component element, and derives visible light radiation generated by discharge in a discharge space formed therein. In the present invention, as the translucent ceramic not containing silicon (Si) as a component element, for example, polycrystalline structures such as translucent alumina, yttrium oxide (YOX), YAG and aluminum nitride (AlN), and single crystals Structures can be used, both of which are refractory materials that are both translucent and sufficiently withstand the normal operating temperature of the lamp. YAG is yttrium-aluminum-garnet (Al ₁₀ Y ₆ O ₂₄ or Al ₅ Y ₃ O ₁₂ (differs depending on the firing temperature)). If necessary, it is allowed to form a halogen-resistant or metal-resistant transparent coating on the inner surface of the hermetic container or to modify the inner surface of the hermetic container.

  Moreover, the airtight container is provided with a surrounding portion in order to form a discharge space therein. The inside of the enclosure, that is, the discharge space is allowed to have an appropriate shape, for example, a spherical shape, an elliptical spherical shape, a substantially cylindrical shape, or the like. Various values can be selected as the volume of the discharge space according to the rated lamp power of the high-pressure discharge lamp, the distance between the electrodes, and the like. For example, in the case of a liquid crystal projector lamp, it can be 0.1 cc or less. In the case of a vehicle headlamp, it can be 0.05 cc or less. Moreover, in the case of the lamp for general illumination, it can be set to either 1 cc or more and the following according to rated lamp electric power.

  Moreover, a pair of sealing part can be provided in the both ends of the surrounding part. The pair of sealing portions are means for sealing the surrounding portion, supporting the shaft portion of the electrode, and contributing to airtight introduction of current from the lighting circuit to the electrode. As a sealing means for an airtight container made of translucent ceramics, for example, a frit seal in which a frit material is poured between the translucent ceramics and a power supply conductor and sealed, or a metal seal using metal instead of the frit material, etc. Can be used. Further, in order to maintain the lowest temperature of the discharge space formed in the hermetic container at a desired relatively high temperature while maintaining the sealing part of the hermetic container at a required relatively low temperature, it communicates with the enclosure part. A small-diameter cylindrical portion can be formed. In such a structure, the sealing portion is disposed at the end portion of the small-diameter cylindrical portion, and the electrode shaft is extended into the small-diameter cylindrical portion so that the capillary and the inner surface of the small-diameter cylindrical portion are interposed between the electrode shaft and the inner surface of the small-diameter cylindrical portion. In general, a slight gap is formed along the axial direction of the small-diameter cylindrical portion. The base end of the electrode is connected to the power supply conductor.

  [About a pair of electrodes] A pair of electrodes are sealed in an airtight container and arranged so as to face the discharge space. In the case of a liquid crystal projector or the like, the interelectrode distance formed between the pair of electrodes is preferably 2 mm or less, more preferably 1 mm or less, and may be, for example, about 0.5 mm. For headlamps, a center value of 4.2 mm is standardized. In the case of a general illumination lamp, it can be set to 6 mm or less for a small lamp with a small distance between electrodes, and to 6 mm or more for a medium or large lamp.

  Further, the constituent material of the electrode is fire-resistant and conductive metal, such as pure tungsten (W), dopant (for example, scandium (Sc), aluminum (Al), potassium (K) and silicon (Si). Or the like, a doped tungsten containing one or a plurality selected from the group of the above, a tritium tungsten containing thorium oxide, a rhenium (Re) or tungsten-rhenium (W-Re) alloy, or the like. it can.

  Furthermore, in the case of a small high-pressure discharge lamp, a straight rod-shaped wire or a wire with a large diameter formed at the tip can be used as the electrode. In the case of a medium or large electrode, a coil made of an electrode constituent material can be wound around the tip of the electrode shaft. Note that the pair of electrodes have the same structure when operated with alternating current, but when operated with direct current, the anode generally has a large temperature rise, so that the heat radiation area is larger than the cathode, and therefore the main part should be thick. Can do.

  [Ionization Medium] The ionization medium is a characteristic component of the present invention, and includes thulium (Tm) halide, aluminum (Al) or aluminum halide and a rare gas, and is essentially free of mercury. is there.

    (About thulium (Tm) halide) Thulium halide is sealed at a maximum sealing ratio in an ionization medium sealed in an airtight container, preferably 40 to 90% by mass in addition to this condition. Radiate. Thulium halide itself has the effect of increasing the potential gradient between the electrodes, and thus the lamp voltage, in the presence of aluminum (Al) or aluminum halide described later, and is suitable as a mercury-free lamp. It is a halide of a luminescent metal. As the halogen of thulium halide, iodine is suitable because it has an appropriate reactivity. However, if desired, either bromine or chlorine may be used, and any desired two or more of iodine, bromine and chlorine may be used. May be used.

  Thulium halide is a light-emitting metal that is extremely effective in improving luminous efficiency because its vapor pressure is low but the peak of thulium emission coincides with the peak of the visibility curve. The emission intensity of thulium greatly depends on the operating temperature during lighting of the high-pressure discharge lamp, and the efficiency becomes maximum under the condition that the coldest part temperature is about 800 ° C. When the hermetic container is made of ceramics, there is no problem in operation under conditions where the coldest part temperature is about 800 ° C., and the chemical resistance is strong. In the present invention, thulium halide is sealed in a lamp. Does not adversely affect lifetime and luminous flux maintenance factor. That is, thulium halide is a luminescent metal halide suitable for a high-pressure discharge lamp using an airtight container made of translucent ceramics.

  Furthermore, the above-mentioned preferable enclosure ratio range of thulium halide will be described. That is, thulium halide is generally a powder in the case of iodide, which is a preferred embodiment, and when its encapsulation ratio increases, it becomes difficult to form solid shapes such as pellets that are easy to handle in lamp manufacture. In the case of thulium bromide, pellets and other solid forms are easier than iodide, but if the bromine encapsulation ratio is too high, electrode damage increases, lamp life is shortened, and light flux is maintained. The rate drop becomes remarkable. Therefore, from the viewpoints of lamp manufacture, lamp life, and luminous flux maintenance factor, the thulium halide encapsulation ratio is preferably less than 80% by mass. Further, from the viewpoint of luminous efficiency, the luminous efficiency peaks when the thulium halide encapsulation ratio is in the range of 50 to 60% by mass. Further, the thulium halide contributes to securing an appropriate lamp voltage in the mercury-free high-pressure discharge lamp as described above, and the lamp voltage increases as the encapsulation ratio of thulium halide increases.

(About aluminum or aluminum halides) Aluminum or aluminum halides, such as aluminum iodide and aluminum bromide, act as buffer substances, have high vapor pressure, a large collision cross section with electrons, and a high ionization potential. Therefore, it is a material suitable as a lamp voltage forming medium in place of mercury in combination with the above-described airtight container. The temperature at which the vapor pressure of AlI ₃ is 1 atm is 361 ° C., and the temperature at which the vapor pressure of AlBr ₃ is 1 atm is 256 ° C. Moreover, the suitable enclosure ratio of aluminum or aluminum halide is 30 mass% or less of the whole ionization medium. Preferably it is 5-20 mass%.

    (Regarding Noble Gas) The noble gas mainly acts as a buffer gas and a starting gas. One kind of a group such as argon (Ar), neon (Ne), and xenon (Xe) can be used alone or a plurality of kinds can be mixed and sealed. The enclosure pressure of the rare gas can be appropriately set according to the use of the high pressure discharge lamp.

  Among the rare gases, xenon has a relatively low thermal conductivity because its atomic weight is larger than other rare gases. Therefore, by enclosing it at 1 atmosphere or more, preferably 5 atmospheres or more, the lamp voltage immediately after lighting is increased. It contributes to the formation and emits white visible light at a stage where the vapor pressure of the halide is low and contributes to the rise of the luminous flux, which is effective in the case of a high-pressure discharge lamp for a headlamp. In this case, the preferable sealing pressure of xenon is 6 atmospheres or more, more preferably in the range of 8 to 16 atmospheres. Therefore, it is possible to satisfy the standards of white light emission as a HID light source for a vehicle headlamp and a rising of a light beam immediately after lighting.

    (Other Halides) Thulium halide, aluminum or aluminum halide and rare gas are essential ionization media in the present invention as described above, but the present invention allows the inclusion of the following halides as subcomponents. To do.

  1. (Alkali metal) When the alkali metal is sealed, it is allowed within a range of less than 10% by mass with respect to all the metal halides sealed in the hermetic container. When the sealing ratio of the alkali metal is 10% by mass or more, the lamp voltage tends to decrease, which is not preferable from the viewpoint of forming the lamp voltage. However, if the sealing ratio of the alkali metal is less than 10% by mass, a decrease in lamp voltage is suppressed to the minimum, while light emission efficiency, lamp life improvement, and light color adjustment, particularly color deviation improvement are possible. From such a point of view, when a required lamp voltage can be ensured, sealing is permitted within the above range. In addition, Preferably it is 2-8 mass%, More preferably, it is 3-7 mass%, More preferably, it is 4-6 mass%. Further, as the alkali metal, it is possible to selectively enclose mainly sodium (Na), but / or if desired, and / or at least one of cesium (Cs) and lithium (Li).

  Sodium (Na) mainly contributes to the improvement of luminous efficiency. Cesium (Cs) contributes to the improvement of life characteristics by optimizing the discharge arc temperature. Lithium (Li) contributes to the improvement of red color rendering.

  2. (Halogens of other rare earth metals) In addition to thulium halides, the following metal halides can be encapsulated mainly as luminescent metal halides. One or a plurality of halides of rare earth metals in the group consisting of praseodymium (Pr), cerium (Ce), holmium (Ho), neodymium (Nd) and samarium (Sm).

  The rare earth metal is useful as a luminescent metal next to thulium halide, and is allowed to be encapsulated at an encapsulation ratio of a predetermined amount or less. That is, any of the rare earth metals has an infinite number of bright line spectra in the vicinity of the peak wavelength of the visibility characteristic curve, and thus can contribute to an improvement in luminous efficiency.

  In addition, when the rare earth metal halide is added, it is preferable that the encapsulation ratio with respect to the total ionization medium including the thulium (Tm) halide is 50 mass% or more.

  3. (Thallium or / and indium halide) The thallium (Tl) and / or indium (In) halide is selectively encapsulated as a secondary component for the purpose of obtaining a desired color rendering property and / or color temperature. It is acceptable. Indium is also effective as a lamp voltage forming medium.

  The thallium (Tl) halide can add a green component of thallium having an emission line at a wavelength of 535 nm during light emission. In addition, it is desirable that the enclosure ratio range of thallium halide that can be generally adopted is less than 30% by mass with respect to all the metal halides to be enclosed. When the enclosure ratio range of thallium halide is 30% by mass or more, the decrease in luminous efficiency becomes significant. In addition, it is preferable to enclose within a range of less than 15% by mass.

  Further, by adding indium (In) halide, the blue component can be increased during light emission of the halide, and also contributes to the formation of a lamp voltage.

  4). (Lamp Voltage Forming Medium Other than Aluminum) A metal halide such as zinc (Zn) halide can be mainly added to aluminum or aluminum halide as the lamp voltage forming medium. Examples of metal halides other than zinc include magnesium (Mg), iron (Fe), cobalt (Co), chromium (Cr), nickel (Ni), manganese (Mn), aluminum (Al), antimony (Sb), beryllium ( One or a plurality of metal halides selected from the group consisting of Be), rhenium (Re), gallium (Ga), titanium (Ti), zirconium (Zr), and hafnium (Hf) can also be added.

    (Mercury) In the present invention, it is preferable not to contain mercury (Hg) at all in order to reduce environmentally hazardous substances.

(Preferred Aspect of Ionization Medium) In the present invention, the following configuration can be adopted as one of the preferred aspects of the ionization medium described above. That is, the metal ionization potential of all metal halides is configured to be 5.4 eV or more. With this configuration, the luminous efficiency is further increased. Next, ionization potentials (eV) of main metals that can be sealed as halides in the hermetic container in the present invention are shown in parentheses after the metal element symbols.
(1) Metal that mainly emits light: Tm (6.18), Pr (5.42), Ce (5.47), Sm (5.63), In (5.786), Tl (6.108)
(2) Metals that mainly contribute to lamp voltage formation: Al (5.986), Zn (9.394), Mg (7.644), Fe (7.87), Co (7.864), Cr (6 .765), Ni (7.635), Mn (7.432), Sb (8.642), Bi (7.287), Re (9.332), Ga (5.999), Ti (6. 84), Zr (6.837),
Hf (7)
In contrast, alkali metals such as Na (ionization potential 5.14 eV) and Li (5.392) have an ionization potential of less than 5.40 eV, and the lamp voltage decreases as the amount of sealing increases. Therefore, in this embodiment, the alkali metal is not substantially contained.

  [Other Configurations] In the present invention, the following configurations can be selectively added as desired.

1. (Outer tube) The component provided with the airtight container, the pair of electrodes, and the ionization medium can be used as an arc tube, and the arc tube can be disposed inside the outer tube. In this case, the outer tube can be any desired shape and size. Further, the inside of the outer tube may be airtight with respect to the outside, or may be communicated with the outside air. In the former case, an inert gas such as argon (Ar) or nitrogen (N ₂ ) can be sealed as required. Furthermore, the outer tube can be formed using a translucent material such as quartz glass, hard glass, or soft glass.

  2. (Reflection mirror) An airtight container can be fixedly disposed at a predetermined position in the reflection mirror. In addition, the structure which consists of a glass base | substrate which formed the dichroic mirror in the inner surface is employable as a reflective mirror.

  [Regarding the Action of the Present Invention] In the present invention, the ionization medium is sealed as a maximum sealing ratio among all metal halides sealed in an airtight container made of a translucent ceramic not containing silicon as a component element. By including a thulium (Tm) halide, the coldest part temperature of the high-pressure discharge lamp can be set to about 800 ° C. at which thulium emits light most efficiently. For this reason, thulium light emission occurs with high efficiency, and becomes the dominant center of light emission of the high-pressure discharge lamp. The emission of thulium has a lot of emission lines near the peak wavelength of 555 nm of the visibility curve, so that a high-pressure discharge lamp having high luminous efficiency as a whole can be obtained.

  Also, aluminum or aluminum halide vapor sealed together with thulium halide acts as a buffer gas to make the high-pressure discharge lamp mercury-free. In addition, a lamp voltage equivalent to that of a high-pressure discharge lamp containing mercury can be formed, and the airtight container does not cause white turbidity or cracks and does not affect the life characteristics.

  In addition, thulium has a higher ionization potential than alkali metals such as sodium, and not only does thulium halide encapsulation not cause a decrease in lamp voltage, but surprisingly in the presence of aluminum or aluminum halide. The present inventors have found that the lamp voltage is increased in proportion to the amount of sealing. If the lamp voltage is increased, it is easy to avoid an increase in lamp current when the required lamp power is applied, so that the design of the electrode and the airtight container is facilitated.

  Furthermore, in the present invention, since the hermetic container is made of a translucent ceramic and can be formed by molding, the dimensional accuracy of the hermetic container is increased, so that the individual characteristics of the lamp are less varied, and the excellent mercury-free high pressure A discharge lamp is obtained.

  Furthermore, in the present invention, the rated lamp power of the metal halide lamp can be set freely from a wide range of values, for example, can be set to an arbitrary value of several kW or less. It can be used in various ways and is suitable, for example, for automotive headlamps, projections, and general lighting. Accordingly, an airtight container having an appropriate shape and size, an appropriate distance between electrodes, and an appropriate amount of discharge medium can be provided depending on the rated lamp power and application.

  Furthermore, the luminous efficiency of the high-pressure discharge lamp can be largely maintained by setting the ionization potential of all the substances constituting the ionization medium to 5.40 eV or more.

  However, by adding sodium halide in the ionization medium in the range of less than 10% by mass, the luminous efficiency of the high-pressure discharge lamp can be further increased while minimizing the decrease in lamp voltage.

  According to the present invention, the thulium halide encapsulated in the ionization medium in the maximum encapsulation ratio is caused to emit light in the state with the highest luminous efficiency, and a high lamp voltage is ensured mainly by aluminum or aluminum halide. A mercury-free high-pressure discharge lamp having excellent lamp characteristics can be provided.

  Hereinafter, embodiments for carrying out the present invention will be described with reference to the drawings.

    FIG. 1 is a cross-sectional view showing a first embodiment for carrying out the high-pressure discharge lamp of the present invention. In the figure, the high-pressure discharge lamp includes an airtight container 1, a pair of electrodes 2 and 2, a power supply conductor 3 and 3, frit glasses 4 and 4, and an ionization medium.

  The hermetic container 1 is made of translucent alumina ceramics and includes an enclosing portion 1a and a pair of sealing portions 1b and 1b. The surrounding portion 1a is hollow and has an outer shape formed into a spindle shape, and a discharge space 1c having a spindle shape is formed therein. Each of the pair of sealing portions 1b and 1b includes a small-diameter cylindrical portion that integrally extends outward from both ends of the surrounding portion 1a in the tube axis direction along the tube axis direction.

  The pair of electrodes 2 and 2 is made of a doped tungsten wire, and the diameter of the shaft portion is the same over the distal end portion, the intermediate portion, and the proximal end portion in the axial direction, and a part of the distal end portion and the intermediate portion is in the discharge space 1c. The main part of the intermediate part is exposed and extends in the sealing parts 1b and 1b by forming a slight gap g in the periphery.

  The pair of power supply conductors 3 and 3 are made of rods such as niobium (Nb) and tantalum (Ta). And each front-end | tip part is inserted in the sealing part 1b of the airtight container 1, and it welds to the base end part of the electrode 2, and the base end part is exposed outside.

  The pair of frit glasses 4, 4 seals the airtight container 1 in cooperation with the sealing portion 1 b and the introduction conductor 3. Then, the lead conductor 3 in a portion inserted into the sealing portion 1 b is covered and reaches the periphery of the base end portion of the electrode 2.

  The ionization medium contains thulium halide, aluminum or aluminum halide, and a rare gas, and is enclosed in the hermetic container 1.

  Example 1 relates to the high-pressure discharge lamp shown in FIG.

Airtight container: maximum outer diameter 6.2 mm, maximum inner diameter 4.4 mm, enclosure length 9.2 mm,
Sealing part outer diameter 1.9 mm, length 12.4 mm, total length 34.0 mm,
Internal volume 0.094cc,
Electrode: Made of tungsten, shaft diameter 0.3 mm, total length 12 mm,
Distance between electrodes 4.2mm
Introduced conductor: Niobium,
Discharge medium: AlI ₃ (14.3) -InI (2.0) -TlI (22.0)-
TmI ₃ (61.7) = 10 mg, Xe1 atmosphere
The number in parentheses is the enclosing ratio (mass%)
Electrical characteristics: Lamp voltage 80V, lamp current 0.44A, lamp power 35W
Lamp characteristics: total luminous flux 2880 lm, luminous efficiency 82 lm / W, color temperature 4600K,
Average color rendering index Ra80

Discharge medium: AlI ₃ (12.5) -InI (1.8) -TlI (7.2)-
_{TmI 3 (69.0) -NaI (9.5} ) = 10mg, Xe1 atm
The number in parentheses is the enclosing ratio (mass%)
Others are the same as Example 1.

Electrical characteristics: Lamp voltage 72V, lamp current 0.494A, lamp power 35W
Lamp characteristics: total luminous flux 3100lm, luminous efficiency 89lm / W, color temperature 4300K,
Average color rendering index Ra76

FIG. 2 is a sectional view showing a second embodiment for carrying out the high-pressure discharge lamp of the present invention. This embodiment is different in that the surrounding portion 1a of the translucent airtight container 1 is cylindrical.

  Example 1 relates to the high-pressure discharge lamp shown in FIG.

Airtight container: maximum outer diameter 11.3 mm, maximum inner diameter 9.1 mm, enclosure length 14.0 mm,
Sealing portion outer diameter 2.6 mm, length 14.0 mm, total length 47.0 mm,
Internal volume 0.976cc,
Electrode: Made of tungsten, shaft diameter 0.4 mm, total length 14 mm,
Distance between electrodes 9.0mm
Introduced conductor: Niobium,
Discharge medium: AlI ₃ (10.5) -TlI (10.5) -TmI ₃ (61.7)
= 10 mg, Xe 1 atm, the number in parentheses is the encapsulation ratio (mass%)
Electrical characteristics: Lamp voltage 86V, lamp current 2.0A, lamp power 150W
Lamp characteristics: total luminous flux 12600lm, luminous efficiency 84lm / W, color temperature 4800K,
Average color rendering index Ra85

Discharge medium: AlI ₃ (10.5) -TlI (10.5) -TmI ₃ (70.7)-
NaI (8.3) = 20 mg, Xe1 atmosphere
The number in parentheses is the enclosing ratio (mass%)
Others are the same as Example 3.

Electrical characteristics: Lamp voltage 69V, lamp current 2.5A, lamp power 150W
Lamp characteristics: total luminous flux 13400lm, luminous efficiency 89lm / W, color temperature 4500K,
Average color rendering index Ra81

Sectional drawing which shows the 1st form for implementing the high pressure discharge lamp of this invention Sectional drawing which shows the 2nd form for implementing the high pressure discharge lamp of this invention

Explanation of symbols

  DESCRIPTION OF SYMBOLS 1 ... Airtight container, 1a ... Enclosing part, 1b ... Sealing part, 1c ... Discharge space, 2 ... Electrode, 3 ... Feeding conductor, 4 ... Frit glass, g ... Capillary

Claims (4)

An airtight container made of translucent ceramics having a discharge space inside and containing no silicon (Si) as a component element;
A pair of electrodes sealed in an airtight container and facing the discharge space;
An ionization medium comprising a maximum encapsulating ratio of thulium (Tm) halide, aluminum (Al) or aluminum halide and a noble gas, essentially free of mercury and enclosed in an airtight container;
A high-pressure discharge lamp comprising: 2. The high pressure discharge lamp according to claim 1, wherein the ionization medium has an ionization potential of 5.40 eV or more. The high-pressure discharge lamp according to claim 1 or 2, wherein the ionization medium contains less than 10% by mass of sodium (Na) halide. 4. The high-pressure discharge lamp according to claim 1, wherein aluminum (Al) or aluminum halide is 30% by mass or less of the entire ionization medium.

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