JPH0589849A - High pressure discharge lamp - Google Patents

Abstract

PURPOSE:To prolong the lifetime of a high pressure discharge lamp by accommodating therein a plurality of light emitting tubes in its single outer tubing in the condition that they are connected parallelly in electrical terms, allowing either of the light emitting tubes to make electric discharge and emit light, and thereby providing possibility of starting the other tube in case one tube goes in leakage without risk of generating electric discharge in the outer tubing. CONSTITUTION:An inert gas is encapsulated in an outer tubing 1 so that the discharge in outer tubing occurs in case a voltage exceeding the discharge starting voltage of light emitting tubes 5a, 5b is impressed. Thus the outer tubing is filled with inert gas to such a level that a voltage around the discharge starting voltage of light emitting tube does not initiate the electric discharge in outer tubing, so that the other tube can be started certainly even in the event of leakage at one of the tubes when no discharge in outer tubing will take place.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a high pressure discharge lamp having two arc tubes housed in an outer tube.

[0002]

2. Description of the Related Art In a high-pressure metal vapor discharge lamp such as a high-pressure sodium lamp or a metal halide lamp, the internal pressure of the arc tube becomes 1 atmospheric pressure or more during lighting, so when the lamp is restarted after the lamp is turned off, the arc tube cools down to some extent. It is necessary to wait for the mercury and the enclosed luminescent metal to aggregate and the internal pressure to drop. For example, in the case of a high-pressure sodium lamp with an external starter, it takes about 1 minute as the restart time, and in the case of a metal halide lamp, it takes 10 minutes or more to wait, and even after restarting, a stable lighting state is reached. I have to wait a few more minutes.

Therefore, for example, if there is a momentary power failure or the like, in the case of an incandescent lamp or a fluorescent lamp, the lamp is immediately turned on, but in the case of the above-mentioned high-pressure metal vapor discharge lamp, it is necessary to wait for 10 minutes or more until full power is exhibited. In addition, it is inconvenient when used for road lighting or tunnel lighting.

To improve this, USP 4,287,
As described in Japanese Patent No. 454, a high pressure sodium lamp in which two arc tubes are housed in an outer tube and these arc tubes are electrically connected in parallel has been proposed.

In the case of this lamp, one of the arc tubes is normally lit during normal operation, and when the power failure is resolved by extinguishing the lamp by a momentary power failure, the other arc tube having a low internal pressure that has not been lit up until then. Lights up. In this case, since the other arc tube is preheated when the one arc tube is lit, the internal pressure is increased, and thus the stable lighting state is reached in a few minutes. Therefore, the restart time is extremely short, which is convenient for the above-mentioned road lighting and tunnel lighting.

Moreover, in such a lamp, even if one of the arc tubes is difficult to light, the other arc tube is lit, so that the life of the lamp is significantly extended, and theoretically, one arc tube is accommodated. 2 times the life of the lamp.

[0007]

By the way, in the case of a lamp in which two arc tubes are electrically connected in parallel to each other and accommodated in the outer tube as described above, for example, in the case of a high-pressure sodium lamp, the two arc tubes are manufactured. The starting voltage slightly fluctuates due to the variation, and the arc tube having a lower starting voltage is more likely to start, so that the arc tube is shifted and started. That is, one of the two arc tubes, which is easy to start, is intensively started at every normal start, and the frequency of use of the arc tube increases. For this reason,
In this arc tube, sodium reacts with the ceramics of the arc tube and disappears, leading to an increase in the lamp voltage, and further, the airtightness of the arc tube is impaired and a leak occurs.

When one of the luminous tubes leaks due to poor airtightness, the xenon enclosed in the luminous tube diffuses into the outer tube. The inside of the outer tube is originally a vacuum, but due to the leakage of xenon, it becomes a dilute atmosphere of xenon gas.

In such a state, the discharge starting voltage in the outer tube filled with xenon gas may be lower than the discharge starting voltage of the arc tube, and when a high voltage pulse is applied to light the other arc tube, Before the discharge tube starts discharge, the conductive parts in the outer tube may generate discharge in the outer tube.

Such discharge in the outer tube becomes glow discharge of xenon and does not lead to arc discharge that causes light emission, and therefore the lamp does not emit light. Therefore, if a leak occurs in one of the arc tubes, the other arc tube does not substantially emit light, and it is expected that the life will be twice as long as that of the lamp containing one arc tube as described above. In addition, there is a drawback that the lamp life is not extended. In addition, such discharge in the outer tube may damage the outer tube.

The present invention has been made in view of the above circumstances. It is an object of the present invention to prevent discharge in the outer tube from occurring even if one of the arc tubes leaks and to prevent the discharge of the other arc tube. An object of the present invention is to provide a high pressure discharge lamp that can be started and has a long lamp life.

[0012]

SUMMARY OF THE INVENTION According to the present invention, a plurality of arc tubes are housed in the same outer tube in a state in which the arc tubes are electrically connected in parallel, and one of the arc tubes is discharged. In the high-pressure discharge lamp adapted to emit light, an inert gas is enclosed in the outer tube so that a discharge in the outer tube is finally generated when a voltage exceeding the discharge starting voltage of the arc tube is applied. And

[0013]

According to the present invention, since the outer tube is filled with the inert gas so that the discharge in the outer tube does not occur at a voltage about the discharge start voltage of the light emitting tube, one of the light emitting tubes causes the airtightness defect. Even if there is a leak, discharge inside the outer tube does not occur, so that the other arc tube can be reliably started.

[0014]

DESCRIPTION OF THE PREFERRED EMBODIMENTS The present invention will be described below with reference to an embodiment shown in FIG.

The figure is a front view showing the structure of a high-pressure sodium lamp, and 1 is an outer tube made of hard glass or the like.
The outer tube 1 has a BT shape with a base 2 attached to one end, and the base 2 is a screw-type base having a shell 3 and an eyelet terminal 4. The outer tube 1 includes two arc tubes 5a, 5
b is accommodated.

Each of the arc tubes 5a and 5b is constructed by hermetically bonding an end cap made of alumina ceramic to the end portion of a bulb made of a ceramic tube such as polycrystalline alumina or single crystal alumina. .. The conductive structures 6 ... Are pierced through the end caps in an airtight manner, and the main electrodes 7 are connected to the conductive structures 6. These main electrodes 7 are opposed to each other with a space therebetween in the arc tubes 5a and 5b. Such arc tubes 5a and 5b are filled with sodium, mercury, and xenon gas.

The conductive structures 6, 6 located on the upper side of the drawing are
It is electrically and mechanically connected to a valve holder 8 made of a heat resistant metal such as niobium or tantalum. Both ends of this valve holder 8 are connected to a support wire 9.

The lower conductive structures 6, 6 are supported by an insulating holder 10 made of alumina ceramic or the like.
Both ends of the insulating holder 10 are fixed to the support wire 9. Therefore, the two arc tubes 5a and 5b
Are arranged side by side in the outer tube 1.

The support wire 9 is made of a conductive wire,
The whole is frame-shaped. The upper end of the support wire 9 is locked to the top of the outer tube 1 via elastic plates 11 and 11. The lower end of the support wire 9 has a stem 12
It is welded to one of the pair of sealing support wires 13a and 13b which are sealed to each other. These sealing support wires 13a and 13b are connected to the shell 3 of the base 2 and the eyelet terminal 4 via the external conducting wires 14a and 14b. The conductive structures 6, 6 below the respective arc tubes 5a, 5b
Is welded to the other sealing support wire 13b through the lead wires 15a and 15b.

Then, on the outside of each arc tube 5a, 5b,
Proximity conductors 16a and 16b are provided for starting assistance. These proximity conductors 16a and 16b are made of, for example, bimetal, one end of which is welded to the support wire 9 and the other end of which faces the outer surfaces of the arc tubes 5a and 5b. When the temperature of the proximity conductors 16a and 16b is lower than a predetermined temperature, the tips of the conductors approach the outer surfaces of the arc tubes 5a and 5b.
It is designed to get away from a. In order to prevent discharge inside the outer tube 1, nitrogen N ₂ is filled as an inert gas, for example, at about 400 Torr in such outer tube 1. 1
7 is a getter. The operation of the lamp having such a configuration will be described.

Before the lamp is started, since the inside of the outer tube 1 and the arc tubes 5a and 5b are cold, the proximity conductor 1 made of bimetal is used.
The tips of 6a and 16b are close to the outer surfaces of the arc tubes 5a and 5b.

When a starting pulse is applied between the shell 3 of the base 2 and the eyelet terminal 4 from a lighting circuit (not shown), one of the main electrodes 6 of the arc tube 5a or 5b, which is easier to start, and the proximity conductor. A starting discharge is generated between the main electrodes 6a and 16b, and this starts a main discharge between the main electrodes 6 and 6. Therefore, the arc tube 5a or 5b that is easier to start
Lights up, and then it shifts to stable lighting.

As described above, when one of the arc tubes, for example, 5a is turned on, if a momentary power failure occurs, it is turned off. Then, when the power failure is resolved, the other arc tube 5b, which has not been illuminated until then, is illuminated. in this case,
The other arc tube 5b is preheated when the one arc tube 5a is turned on, and the internal pressure is slightly increased, so that a stable lighting state is reached in a short time. Therefore, the restart time is extremely short, and the brightness can be restored in a short time when used for road lighting or lighting in tunnels, so that safety can be improved.

When the arc tube lights up, the proximity conductor 16
a and 16b are heated and deformed, and arc tubes 5a and 5a,
Leave 5b. Therefore, it is possible to reduce the blocking of the light emitted from the arc tube by the adjacent conductors 16a and 16b.

Then, the arc tube which is easier to start is biased and started, and the frequency of use of this arc tube becomes high, and the disappearance of sodium progresses due to the reaction between sodium and alumina in this arc tube, and the lamp voltage rises. For example, when the arc tube becomes poor in airtightness and leaks due to the above reasons, the xenon gas enclosed in the arc tube leaks into the outer tube 1.

However, since the outer tube 1 is filled with nitrogen gas at a high pressure, even if the xenon gas leaks from the arc tube, such a leakage of xenon causes the atmosphere inside the outer tube to cause discharge in the outer tube. Therefore, even if the starting voltage of the arc tube is applied, the discharge in the outer tube is prevented.

That is, the ease of discharge varies depending on the type of inert gas, but also on the filling pressure. When the outer tube 1 is evacuated as in the conventional case, the leaked xenon gas creates a xenon atmosphere in the outer tube, which facilitates the generation of xenon discharge. Even if there is some leakage, the discharge start voltage can be increased, thus preventing discharge in the outer tube. Therefore, even if one of the arc tubes leaks and cannot be lit, the discharge inside the outer tube can be prevented and the other arc tube can be reliably started. Therefore, even if the life of one arc tube is exhausted, the other arc tube lights up and emits light, so that the life of the lamp is longer than that of a lamp containing one arc tube.

For example, in the case of a high pressure sodium lamp having a rated input of 400 W, the arc tubes 5a and 5b are made of a translucent alumina tube having an inner diameter of 7.3 mm, and sodium 6 m is contained inside.
g, 24 mg of mercury, and 25 Torr of xenon gas are enclosed. The distance between the centers of the two arc tubes 5a and 5b is 14
They are arranged side by side so as to have a size of about mm and housed in the outer tube 1. Then, the proximity conductor 16 is provided outside the arc tubes 5a and 5b.
Since a and 16b are provided, these arc tubes 5a and 5b are started by a pulse voltage of about 1500V.

Nitrogen N ₂ gas was supplied to the outer tube 1 at 400 To
rr is enclosed in the outer tube 1. Therefore, in the outer tube 1, when a pulse voltage of about 2000 V is applied between the conductive members having different polarities, an electric discharge in the outer tube occurs.

In the case of such a configuration, a starting pulse voltage of about 4000 V is usually applied to start the lamp. In a normal state, when a starting pulse voltage of about 4000V is applied, either one of the arc tubes 5a and 5b which is started by the pulse voltage of about 1500V starts.

Even if one of the arc tubes leaks, since nitrogen N ₂ gas is enclosed in the outer tube 1, no discharge occurs inside the outer tube at a pulse voltage of about 1500 V or less, and the other tube emits light. Since the tube still starts with a pulse voltage of about 1500V, it has been confirmed that this arc tube does start reliably.

In the present invention, the type of the inert gas sealed in the outer tube 1 is not limited to nitrogen, but may be at least one selected from nitrogen, argon, xenon, krypton and neon. The sealing pressure may be high enough to prevent discharge in the outer tube even when a voltage for starting the arc tube is applied. Further, the present invention is not limited to the high-pressure sodium lamp, and can be implemented with a metal halide lamp, a high-pressure mercury lamp, or the like.

[0033]

As described above, according to the present invention, since the outer tube is filled with the inert gas so that the discharge in the outer tube does not occur at a voltage about the discharge start voltage of the arc tube, one of the light emission Even if the tube causes airtightness and leaks, no discharge occurs inside the outer tube, and therefore the other arc tube can be reliably started. Therefore, even if the life of one of the arc tubes is exhausted, the other of the arc tubes is turned on, so that the lamp life is extended.

[Brief description of drawings]

FIG. 1 is a front view showing a high pressure sodium lamp showing an embodiment of the present invention.

[Explanation of symbols]

1 ... Outer tube, 5a, 5b ... Arc tube, 7 ... Electrode, 9 ... Support wire, 16a, 16b ... Proximity conductor.

Claims (2)

[Claims] 1. A high-pressure discharge wherein a plurality of arc tubes are housed in the same outer tube in a state where these arc tubes are electrically connected in parallel, and one of these arc tubes discharges to emit light. In the electric lamp, a high pressure discharge lamp in which an inert gas is enclosed in the outer tube so as to generate a discharge in the outer tube when a voltage exceeding a discharge starting voltage of the arc tube is applied. 2. The inert gas is at least one selected from nitrogen, argon, xenon, krypton, and neon, and when a voltage exceeding a starting voltage for starting the arc tube is applied. The high pressure discharge lamp according to claim 1, wherein the high pressure discharge lamp is filled with a high voltage that causes discharge in an outer tube.