JPS6364030B2 - - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION The present invention relates to a metal halide lamp which is lit using a mercury lamp ballast and which is filled with scandium halide as a luminescent metal.

Recently, ballasts for mercury lamps with a secondary voltage of 200V class,
In other words, it has been proposed to use a single yoke coil type ballast to start a metal halide lamp.Metal halide lamps are superior in light efficiency and color rendering properties compared to mercury lamps, contributing to energy savings, and are compatible with mercury lamps. It has the advantage that existing mercury lamp equipment can be used as is because it generates a

However, the issues here are the startability of metal halide lamps and higher light efficiency. There are many contradictory aspects between high efficiency and excellent startability, and an important issue is how to best balance these two conditions.

In metal halide lamps, the selection of encapsulated metals is an example of improving light efficiency. In recent years, rare earth metal halides, particularly scandium (Sc) halides, have been attracting attention as substances that emit light in the visible light region or wavelengths with particularly good visibility, and sodium iodide (NaI) is used in the arc tube.
It also tends to be encapsulated in the form of scandium iodide (ScI ₃ ).

However, lamps containing scandium have the disadvantage that the starting voltage is high and the starting time is long.

As a measure to improve starting performance, the use of neon-argon mixed gas, so-called Penning gas, as the rare gas for starting has traditionally been adopted, but this type of Penning gas has little convection effect because it is mainly composed of light neon. Therefore, there is a problem that the light efficiency is reduced.

It is also possible to use sodium oxide (ThO ₂ ) as an emitter, but
ThO ₂ reacts with ScI ₃ to promote the generation of free thorium, which also has the disadvantage of reducing light efficiency due to luminescence.

Recently, a method has been adopted in which a bimetal switch is built into the outer tube, a pulse is generated by the kick voltage generated by the opening of the bimetal switch, and this pulse is applied between the main electrodes to start the motor.
However, the requirements for a pulse generator are
For bimetal switches, the number of pulses generated per unit time is the number of pulses generated per unit time, the pulse potential has reached a certain level, and pulses with too high voltage are not generated. Moreover, there are problems such as high voltage pulses being generated from time to time, resulting in dielectric breakdown.

In view of the above-mentioned circumstances, the present invention was developed from a comprehensive viewpoint of the enclosed material, the enclosed gas, the pulse generating element, and the supply of initial electrons.The present invention provides excellent startability and a light efficiency that is 1.6 times or more compared to a mercury lamp. The object of the present invention is to provide a metal halide lamp which is highly suitable for practical use.

An embodiment of the present invention will be described below with reference to the drawings.

In the figure, numeral 1 is an outer tube, which is filled with nitrogen gas.
A light emitting tube 2 is housed within the outer tube 1 . The arc tube 2 is made of a quartz glass tube, and includes a pair of main electrodes 3 and 4 and an auxiliary starting electrode 5 adjacent to one of the main electrodes 3. As shown in FIG. 3, the main electrodes 3 and 4 are constructed by winding an electrode coil 7 around an electrode shaft 6, and the electrode shaft 6 is made of tungsten containing thorium. is made of pure tungsten. The electrode coil 7 is wound around the electrode shaft 6 in three layers. Incidentally, such electrodes 3 and 4 are coated with scandium oxide (Sc ₂ O ₃ ). The arc tube 2 is filled with predetermined amounts of mercury, scandium iodide (SaI ₃ ), and sodium iodide (NsI), as well as argon (Ar) gas at 20 to 100 torr. Also, this luminous tube 2
Radioactive substances such as promethium are sealed inside as a sealed radiation source for handling purposes.

The arc tube 2 is supported by respective supports 10 and 11 via holders 8 and 9 at both end sealed portions. Note that a getter (not shown) such as barium azide (BaN ₂ ) is attached to one of the holders 8 or 9. A lighting tube 12 is housed within the outer tube 1. The lighting tube 12 is the holding cylinder 1
3 and supported by a support 10. One lead wire 14 of the lighting tube 12 is connected to the support 10, and the other lead wire 15 is connected to the current limiting resistor 1.
6. Current limiting resistor 16 is auxiliary resistor 1
It is connected to the starting auxiliary electrode 5 via 7. A fixed contact 19 of a normally closed bimetal switch 18 is connected to the connection line between the current limiting resistor 16 and the auxiliary resistor 17, and a movable contact 20 of the bimetal switch 18 is connected to a well 22 of a stem 21. There is. This well 22 is connected to the other main electrode 4 via a lead wire 23. Note that this well 22 is connected to a cap 24. The support 10 is also connected to another well 25 sealed to the stem 21, and this well 25 is connected to an eyelet terminal 26 of the base 24. Note that 27 is a heat shield plate.

Such a metal halide lamp is connected to a power source 29 via a 200V class mercury lamp ballast 28 shown in FIG. 2, and used for lighting.

However, in a metal halide lamp having such a configuration, when the power supply 29 is turned on, the secondary voltage of the ballast 28 is applied to the lamp through the ballast 28. Then, since the normally closed bimetal switch 18 is closed, current flows through the current limiting resistor 16 and the lighting tube 12. In the case of the lighting tube 12, the contacts of the lighting tube 12 are opened and closed due to the glow current of the lighting tube 12 itself, and the current is repeatedly interrupted and energized. Therefore, a pulse voltage is generated in the circuit of the lighting tube 12, current limiting resistor 16, and bimetal switch 18 due to the inductance of the ballast. This pulse voltage is applied between the opposing main electrodes 3 and 4, and at the same time is applied via the auxiliary resistor 17 to the starting auxiliary electrode 5 and one of the main electrodes 3 adjacent thereto. Main electrode 3
Since the auxiliary electrode 5 is closer than the opposing main electrode 4,
Glow discharge is started between the main electrode 3 and the auxiliary electrode 5. In this case, since a radioactive substance such as promethium is sealed inside the arc tube 2, this radioactive substance emits beta rays, etc., which triggers the initial electron emission, that is, becomes electron seeds and glows. Allows discharge to occur quickly. This glow discharge immediately shifts to glow discharge between the main electrodes 3 and 4.

Such glow discharge between the main electrodes 3 and 4 continues for several seconds to several tens of seconds. In this case, the lighting tube 12 is repeatedly opened and closed, and therefore pulse voltage is repeatedly generated. As the temperature of the main electrodes 3 and 4 rises due to this repeated pulse, the main electrodes 3 and 4 increase in temperature.
An arc spot is formed on 4, which transforms the glow discharge into an arc discharge. In this case, the rapid transition from glow discharge to arc discharge is due to the adoption of the electrode structure as shown in FIG. 3. In other words, since the electrode shaft 6 is made of tungsten containing thorium, it has good electron emissivity due to the action of thorium, and the main electrode is coated with scandium oxide (Sc ₂ O ₃ ), which also improves electron emissivity. advancing and electrode coil 7
Since it has a three-layer structure, it promotes temperature rise in the second layer, making it easier to form arc spots. In particular, when the electrode coil 7 has three layers, the first layer conducts heat through the electrode shaft 6, and the third layer releases heat into the discharge space, but the second layer Surrounded by the eyes, the temperature tends to rise, thus facilitating the formation of arc spots.

When arc discharge is started between the main electrodes 3 and 4 in this manner, the arc tube current increases and the secondary voltage of the ballast decreases, so that the lighting tube 12 no longer opens or closes. When the temperature of the arc tube 2 gradually rises and reaches a predetermined temperature, the bimetal switch 18 is opened by the heat of the arc tube 2, and current no longer flows through the current limiting resistor 16 and the lighting tube 12. The power supply to the starting auxiliary electrode 5 is cut off,
Maintain stable lighting.

In this way, the metal halide lamp with the above structure can be started reliably and the starting time is shortened even though scandium is used as the enclosed luminescent metal and argon is used as the starting rare gas. Ru. Since the above-mentioned scandium and argongos are used, the light efficiency is more than 1.6 times that of a mercury lamp, and the color rendering properties are also good.
There is also little variation in light color.

Next, an experimental example will be explained. A 400W arc tube with an inner diameter of 20mm and a distance between electrodes of 42mm was assembled as shown in Figure 1. The main electrode uses tungsten containing 1.7% thorium for the electrode shaft, and the coil part is wound in three layers. The main electrode was coated with scandium oxide powder dissolved in butyl acetate and vacuum treated. Inside the arc tube are 60 mg of mercury, 25 mg of sodium iodide (NaI), 5 mg of scandium iodide (ScI ₃ ),
It is filled with 50 torr of argon gas. In addition, promethium (Pm) is sealed inside the arc tube. This promethium is made into a sealed radiation source by replacing the Na component of ceramic zeolite (Na ₂ O-SiO ₂ -Al ₂ O ₃ ) with Pm, and has excellent heat resistance and halogen resistance. There is. The ceramic body has a cylindrical shape with an outer diameter of 1 mm and a length of 2 mm.

The lighting tube used was one that generates a kick voltage of about 1500V.

The current limiting resistor uses a 300Ω carbon film resistor.
The current flowing through the lighting tube is controlled to prevent too high a pulse. Since the heat resistance of the carbon film resistor is limited, the bimetal switch is installed close to the carbon film resistor so that if it does not turn on for more than one minute, the circuit will be opened by the heat of the carbon film resistor. be.

The 400W metal halide lamp configured in this way has an initial efficiency of 105lm/W, an efficiency of 100lm/W after 100 hours of lighting, a color temperature of 4000〓, and an average color rendering index Ra of 65, making it as efficient as a 400W mercury lamp. 1.6 times the brightness of the light, and there is little unevenness in the light color. In addition, when 100 lamps with this configuration were manufactured and tested, 90% of them lit up within 30 seconds at a power supply voltage of 170V using a mercury lamp ballast with a secondary voltage of 200V, and 100% at a power supply voltage of 200V. was lit. Therefore, we were able to confirm the interchangeability with mercury lamps.

Note that the present invention is not limited to the above embodiments.

For example, in addition to Pm, radioactive substances include
²² Na, ²⁶ Al, ³⁶ Cl, ⁶⁰ Co, ⁹⁰ Sr, ¹³⁷ Cs,
Possible examples include ¹³³ Ba, ¹⁴⁴ Ce, ²¹⁰ Pb, and ²²⁸ Th. Further, the sealed radiation source body is not limited to ceramic, but may be one in which the radioactive substance is coated with the same substance as the substance in the arc tube, for example, an element such as W, Si, Na, or Sc.

Further, the glow discharge is started even without using the starting auxiliary electrode, so the present invention is not limited to the embodiment.

As detailed above, according to the present invention, the light efficiency is extremely good, and the light efficiency is more than 1.6 times that of a mercury lamp. Therefore, it is possible to save power by using a mercury lamp ballast instead of a mercury lamp. becomes possible. In addition, this product ensures reliable starting and shortens the starting time, making it extremely useful in practice.

[Brief explanation of drawings]

The drawings show an embodiment of the present invention; FIG. 1 is a partially sectional front view of the lamp, FIG. 2 is a circuit diagram thereof, and FIG. 3 is a sectional view of the main electrode. 1... Outer tube, 2... Arc tube, 3, 4... Main electrode, 6... Electrode shaft, 7... Electrode coil, 12...
Lighting tube, 28...ballast.

Claims (1)

[Scope of Claims] 1. Mercury, scandium halide, and argon gas are sealed in an arc tube equipped with a pair of main electrodes, and a radioactive substance that has been made into a sealed radiation source for handling is sealed, and the arc tube is used to generate pulses. A metal halide lamp characterized in that it is housed in an outer tube together with a lighting tube and used in a ballast for a mercury lamp. 2 The radioactive substance mentioned above is promethium ( ¹⁴⁷ Pm)
The metal hyride lamp according to claim 1, characterized in that: 3. The metal halide lamp according to claim 1, wherein the radioactive substance is dispersed and sealed in a ceramic body to form a sealed radiation source for handling purposes. 4. The metal halide lamp according to claim 1, wherein the main electrode has an electrode coil wound in three layers around the electrode shaft. 5. The metal halide lamp according to claim 1, wherein the electrode shaft is made of tungsten containing thorium. 6. The metal halide lamp according to claim 1, wherein the main electrode is coated with scandium oxide.