JP2013026039A - Metal halide lamp - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a metal halide lamp capable of suppressing sharp decline of lamp voltage in the early time of lighting start.SOLUTION: The metal halide lamp includes a light-emitting tube that includes a pair of electrodes and in which noble gas, mercury, halogen, a light-emitting metal are encapsulated. The light-emitting metal is iron and tin, and thallium as a lamp voltage maintenance component is encapsulated in the light-emitting tube.

Description

  The present invention relates to a metal halide lamp suitable for photochemical reaction including curing of ink, paint, resin and the like.

  Ultraviolet rays are often used for photochemical reactions such as curing inks, paints, resins, etc., but in recent years, instead of high-pressure mercury lamps that have been used as light sources for ultraviolet irradiation, A metal halide lamp in which various light emitting metals are enclosed together with halogen is widely used (Patent Document 1).

  Among such metal halide lamps, those in which iron and tin are encapsulated as light emitting metals have higher luminous efficiency in the ultraviolet region, particularly in the wavelength range of 280 to 420 nm, compared to the high pressure mercury lamp. Suitable for curing inks, paints, resins, etc.

Japanese Patent Publication No.58-18743

  However, the metal halide lamp in which iron and tin are enclosed has a problem that the lamp voltage is suddenly lowered at the beginning of lighting. For this reason, conventionally, when manufacturing a metal halide lamp in which iron and tin are enclosed, the lamp voltage is set to about 10% higher than the standard. However, in the metal halide lamp in which the lamp voltage is set to be high in this way, the light emission intensity may not be stable even if the lamp voltage is stabilized after the aging process.

  Therefore, in view of the above situation, the present invention is intended to provide a metal halide lamp capable of suppressing a rapid decrease in lamp voltage at the beginning of lighting.

  As a result of intensive studies, the present inventor found that a rapid decrease in lamp voltage at the beginning of lighting was suppressed by enclosing thallium together with iron and tin in the arc tube, and completed the present invention. . In addition, in this specification, the lighting start initial stage means within about 16 hours from the lighting start of the metal halide lamp.

  That is, the metal halide lamp according to the present invention is a metal halide lamp in which a rare gas, mercury, halogen, and a luminescent metal are sealed inside an arc tube having a pair of electrodes, and the luminescent metal is It is iron and tin, and further, thallium is enclosed in the arc tube as a lamp voltage maintaining component.

In the present invention, the amount of thallium enclosed in the arc tube is preferably 3.0 × 10 ⁻⁵ mmol / cm ³ or less per unit internal volume.

  A method for suppressing a decrease in lamp voltage at the beginning of lighting by sealing thallium as a lamp voltage maintaining component in an arc tube of a metal halide lamp in which iron and tin are sealed as a light emitting metal is also one aspect of the present invention. is there. That is, the method for suppressing a decrease in lamp voltage according to the present invention is a metal halide lamp in which a rare gas, mercury, halogen, and iron and tin as light emitting metals are sealed inside an arc tube having a pair of electrodes. A method for suppressing a decrease in lamp voltage at the beginning of lighting, characterized in that thallium is enclosed in the arc tube as a lamp voltage maintaining component.

  Since this invention consists of the structure mentioned above, it can suppress the rapid fall of the lamp voltage at the start of lighting. For this reason, according to the metal halide lamp of the present invention, it is not necessary to set the lamp voltage high at the time of manufacture. Stability can be avoided.

It is typical sectional drawing which shows the structure of the metal halide lamp which concerns on one Embodiment of this invention. It is a graph which shows the relationship between the sealing amount of thallium, and a lamp voltage maintenance factor.

Hereinafter, embodiments of the metal halide lamp according to the present invention will be described.
A metal halide lamp according to the present invention includes an arc tube in which a pair of electrodes are arranged to face each other, and a rare gas, mercury, halogen, and a light-emitting metal are sealed in the arc tube. is there.

  As such a metal halide lamp, the thing as shown in FIG. 1 is mentioned, for example. In the metal halide lamp 1, a pair of electrodes 3 are arranged opposite to each other in an arc tube 2 made of quartz glass or translucent ceramic, and molybdenum foil 4 is provided at small diameter portions provided at both ends of the arc tube 2. And a base 5 are provided. As the electrode 3, for example, an electrode in which a tungsten wire is wound a plurality of times in the shape of a coil at the tip of an electrode core bar made of triated tungsten containing tungsten or thorium oxide is used.

  The rare gas is not particularly limited as long as it is generally used for a metal halide lamp, and examples thereof include helium gas, neon gas, argon gas, krypton gas, and xenon gas.

  The mercury may be encapsulated as metallic mercury, but may be encapsulated as mercury halide together with the halogen described below, and metallic mercury and mercury halide may be used in combination.

  The halogen is not particularly limited, and examples thereof include iodine, bromine, chlorine and the like. One of these halogens may be used alone, or two or more thereof may be used in combination. The halogen can be encapsulated as a metal halide together with the above-described mercury, the light emitting metal, or thallium described later.

  In the present invention, iron and tin are enclosed as the luminescent metal. Here, iron and tin function as a main light emitting source of ultraviolet rays, and tin functions as a secondary light emitting metal for improving spectral characteristics. Each of these metals may be encapsulated as a simple metal (metal iron, metal tin), but may be encapsulated as a metal halide (iron halide, tin halide) together with the halogen. A compound may be used in combination. As the light emitting metal, in addition to iron and tin, other known light emitting metals may be appropriately encapsulated according to the intended use and purpose.

In the present invention, the amount of the luminescent metal enclosed in the arc tube is 1.0 × 10 ⁻⁴ per unit internal volume from the viewpoint of the luminescence intensity required for the photochemical reaction including curing of ink, paint, resin and the like. It is preferably 1.5 × 10 ⁻³ mmol / cm ³ .

  The ratio of the amount of iron (Fe) and tin (Sn) enclosed is preferably a molar ratio of Fe / Sn and Fe / Sn = 1-12, more preferably Fe / Sn = 3-5. is there. By encapsulating iron and tin at such a ratio, light in the target wavelength region (around 350 nm) can be stably obtained. Moreover, if iron and tin are enclosed in a ratio within this range, a rapid decrease in lamp voltage at the beginning of lighting can be satisfactorily suppressed by adding thallium described later.

  In the present invention, in addition to rare gas, mercury, halogen, and light emitting metals such as iron and tin, thallium is further enclosed in the arc tube as a lamp voltage maintaining component. Thus, by enclosing thallium in the arc tube, it is possible to suppress a rapid decrease in lamp voltage at the beginning of lighting. The reason why such an effect is exhibited is presumed as follows. That is, the lamp voltage fluctuates depending on the amount of evaporation of the encapsulated material, and the lamp voltage also decreases as the amount of encapsulated material decreases, but the vapor pressure of thallium halide is tin halide or iron halide. Therefore, when thallium is enclosed in the arc tube together with iron and tin in the presence of halogen, the amount of evaporation as the whole encapsulated material increases compared to when only iron and tin are enclosed, As a result, it is considered that the vapor pressure in the arc tube can be improved, and a rapid decrease in lamp voltage at the beginning of lighting can be suppressed.

In the present invention, the amount of thallium enclosed in the arc tube is preferably 3.0 × 10 ⁻⁵ mmol / cm ³ or less per unit internal volume. Even if the amount of thallium exceeding 3.0 × 10 ⁻⁵ mmol / cm ³ is encapsulated, the effect of increasing the maintenance ratio of the lamp voltage is not improved any more, and thallium contributes as a luminescent substance. The light emission efficiency in the wavelength region (near 350 nm) decreases, while green light derived from thallium having a peak wavelength near 535 nm tends to become prominent.

In addition, when the amount of thallium enclosed is 3.0 × 10 ⁻⁵ mmol / cm ³ or less, the effect of maintaining the lamp voltage is improved as the amount of thallium enclosed is increased. The thallium encapsulation amount is preferably 1.5 × 10 ⁻⁶ mmol / cm ³ or more.

  The present invention will be described in more detail with reference to the following examples. However, the present invention is not limited to these examples.

  A UV metal halide lamp having the following specifications was produced as a test lamp.

(1) Lamp specifications Arc tube material: Quartz Arc tube inner diameter: 22mm
Arc tube inner volume: 150 cm ³
Distance between electrodes: 350mm
Filled gas: Argon (2000 Pa)
Lamp power: 5600W

  The following luminescent material was enclosed in a UV metal halide lamp having such specifications.

(2) enclosing a light emitting substance FeI ₂ and SnI _2, the sum is 14mg next, and FeI ₂ and the molar ratio _FeI 2 / SnI ₂ and SnI _{2 is} the lamp so that FeI 2 / _SnI 2 = 5 did. More specifically, 11.28Mg the FeI _2, the SnI ₂ was 2.72mg sealed.

Furthermore, the amount of thallium shown in Table 1 below is enclosed as TlI to prepare each test lamp, which is lit for 16 hours, and the lamp voltage is measured immediately after the start of lighting and after 16 hours from lighting, The maintenance rate was calculated. Note that the lamp voltage immediately after the start of lighting was set to 530 V for all lamps by adjusting the amount of mercury enclosed. Specifically, in a lamp to which TlI is not added, if the mercury filling amount is 178 mg, the lamp voltage immediately after the start of lighting is 530V. The obtained results are shown in Table 1 and FIG. In Table 1 and FIG. 2, “(numerical value) E ± X” represents “(numerical value) × 10 ^{± X} ”.

  From the obtained results, it is confirmed that by enclosing thallium in the arc tube, the thallium enclosed in the arc tube functions as a lamp voltage maintaining component, and a rapid decrease in the lamp voltage at the beginning of lighting is well suppressed. confirmed.

The suppressive effect of thallium on the lamp voltage drop increased as the amount of encapsulation increased, but when the amount of thallium enclosed exceeded 3.0 × 10 ⁻⁵ mmol / cm ³ , the effect was saturated.

  In this test, iodine (I) was used as the halogen, but it was confirmed that the same effect was obtained when bromine (Br) was used as the halogen (data not shown).

DESCRIPTION OF SYMBOLS 1 ... Metal halide lamp 2 ... Arc tube 3 ... Electrode 4 ... Molybdenum foil 5 ... Base

Claims (3)

A metal halide lamp in which a rare gas, mercury, halogen, and a light-emitting metal are sealed inside an arc tube having a pair of electrodes,
The luminescent metal is iron and tin;
The metal halide lamp is characterized in that thallium is enclosed in the arc tube as a lamp voltage maintaining component. 2. The metal halide lamp according to claim 1, wherein an amount of thallium enclosed in the arc tube is 3.0 × 10 ⁻⁵ mmol / cm ³ or less per unit internal volume. Method for suppressing a decrease in lamp voltage at the beginning of lighting of a metal halide lamp in which a rare gas, mercury, halogen, and iron and tin as light emitting metals are sealed inside an arc tube having a pair of electrodes Because
A method for suppressing a decrease in lamp voltage, wherein thallium is enclosed as a lamp voltage maintaining component in the arc tube.