JPH09320520A - Fluorescent lamp - Google Patents

Abstract

PROBLEM TO BE SOLVED: To enhance the startup of a light beam at the first stage of re-lighting of an amalgam-containing fluorescent lamp, particularly a bulb type fluorescent lamp with a globe covering the appearance of its bulb, a compact fluorescent lamp for use at high load, an electrodeless fluorescent lamp, etc. SOLUTION: An assembly 9 of particles having a number of through holes is applied to the surface of a mercury-containing amalgam 1 to restrict the movement of mercury atoms between the amalgam 1 and a discharge space 6a. After a fluorescent lamp has been turned off, the movement of the mercury atoms present in the discharge space is restricted by the assembly 9 of particles, and the amalgam 1 is solidified before all the mercury atoms return to the amalgam 1. As a result, numerous mercury atoms remain in the discharge space 6a, and mercury vapor pressure can be heightened at the initial stage of re-lighting of the fluorescent lamp.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an amalgam-containing fluorescent lamp, and more particularly to a light bulb-type fluorescent lamp in which the outer appearance of a bulb is covered with a globe-type cover or the like.

[0002]

2. Description of the Related Art Since a bulb-type fluorescent lamp is used in place of a conventional incandescent bulb, the arc tube is bent, for example, in a U-shape a plurality of times in order to increase its length, and is made to resemble an incandescent bulb. It is covered with a glove-shaped cover. Therefore, U
Unlike the straight tube fluorescent lamp, the mercury vapor pressure inside the arc tube bent like a letter is susceptible to heat generation during lighting. In order to solve such a problem, for example, as disclosed in Japanese Patent Application Laid-Open No. 62-64044, a conventional fluorescent light in which the mercury vapor pressure in the discharge space inside the arc tube is adjusted within an appropriate range by an amalgam. A lamp (first conventional example) has been proposed. The structure of the first conventional example will be described with reference to FIG. 4, which is a partially cutaway side view of the arc tube.

As shown in FIG. 4, in the first conventional example, a main amalgam 1 for appropriately controlling the mercury vapor pressure during lighting and an auxiliary amalgam 8 for facilitating the release of mercury during the initial lighting are provided. It is provided and is configured to ensure constant brightness from the initial lighting to the end of lighting. The main amalgam 1 is provided at a predetermined position in a thin tube 4 formed near one of the pair of electrodes 7 at both ends of the arc tube 6. The auxiliary amalgam 8 is provided in the vicinity of the electrode 7 so that the entire surface thereof is directly exposed to the discharge space 6a. Since the mercury vapor pressure of the auxiliary amalgam 8 is lower than that of the main amalgam 1, the auxiliary amalgam 8 adsorbs mercury atoms from the main amalgam 1 via the discharge space 6a after the lamp is turned off.

On the other hand, since the bulb-type fluorescent lamp is used in place of the conventional incandescent bulb, its mounting direction is not constant. Therefore, the temperature at the position of the amalgam in the arc tube greatly changes depending on the mounting direction of the fluorescent lamp. As a result, it is difficult to control the mercury vapor pressure in the arc tube within a certain range from the initial lighting to the extinction. In order to solve such a problem, for example, Japanese Patent Laid-Open No.
As disclosed in Japanese Patent Laid-Open No. 0-202652, by containing amalgam in a container and freely moving inside the arc tube, the conventional movable amalgam in which the amalgam is always positioned almost at the bottom of the arc tube is included. Fluorescent lamp (second
Conventional example) has been proposed. The configuration of the second conventional example,
This will be described with reference to FIG. 5, which is a partially cutaway side view of the arc tube, and FIG. 6, which is an enlarged sectional view of the amalgam container.

As shown in FIGS. 5 and 6, in the second conventional example, the main amalgam 1 is housed inside the container 10, and the container 10 is constructed so as to be movable inside the arc tube 6. . Therefore, the main amalgam 1 housed in the container 10 is provided at the lowest position in the direction of gravity regardless of the mounting direction of the fluorescent lamp. The auxiliary amalgam 8 is provided in the vicinity of the electrode 7 whose temperature is higher than that of the main amalgam 1 during lamp lighting. Second
When the fluorescent lamp of the conventional example is turned off, mercury atoms in the discharge space 6a are adsorbed by the auxiliary amalgam 8. When the fluorescent lamp is turned on again, the auxiliary amalgam 8 releases the adsorbed mercury atoms in the initial stage of lighting.

In the above-mentioned first and second conventional examples, a copper-iron ballast circuit with a built-in glow tube was mainly used.
In the initial stage of lighting, the auxiliary amalgam 8 is heated by the filament preheating during the glow tube operation, and the auxiliary amalgam 8
Since mercury is released from the tube, the mercury vapor pressure in the arc tube rises rapidly. Therefore, in the conventional fluorescent lamp,
It was possible to shorten the time from the start of lighting until the brightness reached a certain level (rise of luminous flux). The principles of amalgam operation are described in detail in the Spring 1977 issue of the Journal of IS, pages 141-147.

[0007]

In recent years, even in fluorescent lamps of electric bulb type, it is required to turn on more quickly, and an electronic ballast circuit is replaced with the conventional copper-iron ballast circuit with a built-in glow tube. It has become popular. When the electronic ballast circuit is used in the conventional fluorescent lamp, the time for preheating the filament is too short to sufficiently heat the auxiliary amalgam 8. Therefore, at the initial stage of lighting, the amount of mercury atoms released from the auxiliary amalgam 8 due to filament preheating is small, and it is difficult to maintain the mercury vapor pressure at a certain level or higher at the initial stage of lighting. As a result, if an electronic ballast circuit is used for a conventional fluorescent lamp, it can be turned on instantly,
There is a problem that it takes a long time from the start of lighting to reaching a certain brightness.

In the case of the second conventional example, although the main amalgam 1 is stored inside the container 10,
Since substantially the entire surface of the main amalgam 1 is exposed to the discharge space 6a through the opening 10a, the surface area of the main amalgam 1 is relatively large. Therefore, after turning off the fluorescent lamp,
By the time the main amalgam 1 is solidified, the mercury atoms in the discharge space 6a return to the main amalgam 1 in the container 10 through the openings 10a and are adsorbed on the surface of the main amalgam 1. As a result, the amount of mercury atoms remaining in the discharge space 6a is extremely small. Therefore, there is a problem that it is difficult to maintain the mercury vapor pressure in the discharge space 6a at a predetermined value or higher at the initial stage of relighting of the fluorescent lamp of the second conventional example.

The present invention has been made to solve the above-mentioned problems of the conventional example, and the mercury vapor pressure during lighting is properly controlled without using an auxiliary amalgam, and the rise of luminous flux at the initial stage of relighting is improved. The purpose is to provide a fluorescent lamp.

[0010]

The fluorescent lamp of the present invention comprises:
An arc tube provided with a phosphor layer on the inner surface, an amalgam containing mercury provided at a predetermined position of the discharge space formed by the arc tube, and a fluorescent lamp between the amalgam and the discharge space. It comprises a barrier means for limiting the movement of mercury atoms reciprocating with lighting and extinguishing, the barrier means is composed of an aggregate of fine particles having a plurality of through-holes attached to the surface of the amalgam, the fine particles The total opening area of the aggregate allows the mercury atoms in the amalgam to be supplied to the discharge space while the fluorescent lamp is lit, and before the amalgam solidifies after the fluorescent lamp is turned off, the discharge space It is a size capable of substantially preventing the mercury atoms existing in the above from returning to the amalgam.

In the above structure, the size of the effective portion of each through hole of the aggregate of fine particles has a diameter larger than the diameter of mercury atom when the cross section is converted into a circle, and the total opening area is 0. It is preferably 2 mm ² or less.

The aggregate of the fine particles is preferably selected from zeolite, talc, glass powder and oxides. Further, the oxide is preferably any oxide selected from titanium oxide, aluminum oxide, silicon oxide, magnesium oxide and rare earth metal oxides or a composite oxide of two or more.

In each of the above constructions, it is preferable that a pair of electrodes are provided at both ends of the arc tube, and the amalgam is provided near at least one of the pair of electrodes.

Further, in each of the above constitutions, it is preferable that the amalgam has a base metal made of an alloy containing at least one metal selected from bismuth, indium, tin, lead, zinc and silver.

[0015]

BEST MODE FOR CARRYING OUT THE INVENTION The fluorescent lamp of the present invention will be described below with reference to FIGS. FIG. 1 is a partial cross-sectional view showing a structure of an arc tube of a light bulb shaped fluorescent lamp which is an embodiment of the fluorescent lamp of the present invention, and FIG. 2 is an amalgam 1 in FIG. 1 and a collection of fine particles deposited on the surface thereof. FIG. 3 is an enlarged cross-sectional view showing details of the body 9, and FIG. 3 shows rising relative luminous fluxes in the initial stage of relighting of the fluorescent lamp of the present invention shown in FIG. 1 and the conventional fluorescent lamp shown in FIG. 4 (first conventional example). It is a figure.

As shown in FIG. 1, an arc tube 6 of a light bulb type fluorescent lamp has an inner surface coated with a phosphor layer 5 and is bent in a plurality of U-shapes a plurality of times. ) 7 (the counter electrode is not shown) is formed, and the thin tube 4 is provided in the vicinity of one or both of the electrodes 7. A glass rod 11 and an amalgam 1 containing a bismuth-indium alloy as a base metal and containing about 3% by weight of mercury are housed in the thin tube 4 in this order from the electrode 7 side.

As shown in FIG. 2, an aggregate 9 of fine particles is attached to the surface of the amalgam 1. The aggregate 9 of fine particles functions as a barrier and restricts mercury atoms from reciprocating between the amalgam 1 and the discharge space 6a inside the arc tube 6 when the fluorescent lamp is turned on and off (mercury atoms). To reduce the conductance of movement). The aggregate 9 of fine particles is formed by spraying a dispersion liquid of talc fine powder dispersed in a volatile solvent onto the surface of the amalgam 1. The average particle size of the aggregate 9 of fine particles is about 0.1 μm, and the adhered amount thereof is about 1 mg / cm ² . The effective area size of the through holes formed in the gaps between the fine particles in the aggregate 9 of fine particles is such that the diameter of each through hole is larger than the diameter of the mercury atom when the cross section of each through hole is converted into a circle, and the total opening area is 0.2 m
The size of the amalgam 1 and the density of the aggregates 9 of fine particles are selected so as to be m ² or less. The total opening area of the aggregate 9 of fine particles enables the mercury atoms in the amalgam 1 to be supplied to the discharge space 6a while the fluorescent lamp is lit, and after the fluorescent lamp is turned off, until the amalgam 1 is solidified. In addition, the mercury atoms existing in the discharge space 6a can be substantially prevented from returning to the amalgam 1.

Next, the operating principle of the present invention will be described. During the lighting of the fluorescent lamp, the mercury atoms present in the optimum amount in the discharge space 6a start to move to the amalgam 1 as the temperature decreases after the light is turned off. However, the portion of the amalgam 1 that is in direct contact with the discharge space 6a is only the portion that faces the through holes formed in the gaps between the fine particles in the aggregate 9 of fine particles, and the total opening area thereof is 0. It is an extremely small area of 2 mm ² or less. Therefore, the conductance of migration of mercury atoms is small, and the amalgam 1 is fixed before many mercury atoms reach the amalgam 1. Therefore, the diffusion rate of mercury atoms into the amalgam 1 is extremely slow. Further, after the amalgam 1 is solidified, mercury atoms are adsorbed only on the surface of the amalgam 1 on its microscopic surface. Therefore, the mercury concentration at the interface of the amalgam 1 in contact with the discharge space 6a becomes extremely higher than that of the other parts of the amalgam 1, and the mercury vapor pressure at that part increases. As a result, a decrease in the number of mercury atoms in the discharge space 6a can be suppressed, and the initial luminous flux at the next lighting can be increased accordingly.

A bulb-type fluorescent lamp was prototyped using the above-mentioned arc tube, and the rising luminous flux was measured. As a comparative example,
The rising luminous flux of the bulb-type fluorescent lamp having the conventional configuration shown in FIG. 4 was also measured. The result is shown in FIG. In FIG. 3, the horizontal axis represents the time from the start of relighting of each fluorescent lamp, and the vertical axis represents the maximum luminous flux of each lamp as 100% and the luminous flux of each fluorescent lamp at each measurement time point as a relative value.
The curve A represents the relative luminous flux of the fluorescent lamp of the present invention, and the curve B
Represents the relative luminous flux of a conventional fluorescent lamp. These fluorescent lamps had a built-in electronic lighting circuit that eliminated the filament preheating mode, and after being lit for a long time at an ambient temperature of 25 ° C, they were extinguished for 15 hours and then lit again.

As is apparent from FIG. 3, the curve A relating to the compact fluorescent lamp of the present invention has a relative luminous flux rising from about 40%. On the other hand, in the curve B relating to the conventional fluorescent lamp, the relative luminous flux rises from about 20%.
This is because the mercury vapor pressure by the main amalgam 1 and the auxiliary amalgam 8 of the conventional fluorescent lamp is low at the initial stage of relighting.

Next, the reason why the lighting initial luminous flux of the bulb-type fluorescent lamp of the present invention is increased will be considered below. When the bulb-type fluorescent lamp of the present invention is turned on for a long time, the amalgam 1 has 12
Since it is in a liquid phase state at a temperature of around 0 ° C., mercury is present homogeneously in it and is in gas-liquid equilibrium with the discharge space 6a through the through holes. Therefore, during long-time lighting, the mercury vapor pressure in the discharge space 6a is maintained in an almost optimal state, and a luminous flux close to the maximum luminous flux can be obtained. Then, almost the same amount of mercury consumed in the discharge space 6a of the arc tube 6 is supplied from the amalgam 1 into the discharge space 6a.

Once the fluorescent lamp of the present invention is turned off,
Mercury atoms try to return to Amalgam 1. However, the cross section of the through hole of the aggregate 9 of fine particles is small, and the conductance for the movement of mercury atoms is small. Therefore, only a part of the amount of mercury existing in the discharge space 6a can return to the amalgam 1 while the amalgam 1 exists in the liquid phase state. At this time, the mercury adsorbed on the surface of the liquid phase amalgam 1 can easily diffuse into the amalgam 1.

When the amalgam 1 is solidified, the diffusion rate of mercury into the amalgam is extremely reduced. Amalgam 1
The mercury atoms that have arrived after the solidification of the are adsorbed by being stacked on the surface of the amalgam 1. However, since the area exposed to the discharge space 6a of the amalgam 1 is small, the concentration of mercury near the surface of the amalgam 1 rapidly increases.
When the mercury vapor pressure near the surface of the amalgam 1 becomes almost the same as the mercury vapor pressure of the mercury adsorbed on the aggregate 9 of fine particles, the movement of mercury atoms stops. At this time, most of the amount of mercury existing in the discharge space 6a during lighting remains in the discharge space 6a. Through the above process,
It can be considered that the relative luminous flux at the initial stage of relighting of the fluorescent lamp of the present invention is higher than that of the conventional fluorescent lamp.

Although talc fine powder was used as the aggregate 9 of fine particles in the above description, instead of titanium oxide,
A single oxide or two or more composite oxides selected from aluminum oxide, silicon oxide, magnesium oxide and rare earth metal oxides, or fine particle oxides such as zeolite and glass powder can be used. In addition to the alloy of bismuth and indium as the base metal of the amalgam 1,
An alloy containing any metal of bismuth, indium, tin, lead, zinc, and silver, or an alloy of two or more kinds of metals selected from these may be used. By appropriately selecting the base metal, the change point between the liquid phase and the solid phase of the amalgam 1 can be set to a desired temperature.

Further, although the arc tube 6 bent in a plurality of U-shapes a plurality of times has been described, the arc tube 6 is not limited to this, and it can be said that a straight tube or an annular tube also exhibits the same effect. There is no end.

[0026]

As described above, the fluorescent lamp of the present invention is
An arc tube provided with a phosphor layer on its inner surface, an amalgam containing mercury provided at a predetermined position in the discharge space formed by the arc tube, and a fluorescent lamp being turned on and off between the amalgam and the discharge space. And a barrier means for restricting the movement of mercury atoms that reciprocate with each other. The barrier means is composed of an aggregate of fine particles having a plurality of through holes attached to the surface of the amalgam, and the through holes of the aggregate of fine particles are provided. The total opening area of allows the mercury atoms in the amalgam to be supplied to the discharge space while the fluorescent lamp is lit, and the mercury atoms present in the discharge space before the amalgam solidifies after the fluorescent lamp is turned off. It is a size that can substantially prevent the return. With such a configuration, the mercury vapor diffused in the discharge space after the fluorescent lamp is turned on, after the fluorescent lamp is turned off,
The barrier means limits the return to the amalgam, and most of the mercury atoms remain in the discharge space. Therefore, the mercury vapor pressure in the discharge space is maintained at a constant value or higher in the initial stage of relighting of the fluorescent lamp, the rise of the luminous flux immediately after relighting becomes steep, and a sufficient luminous flux can be secured. Further, as the mercury vapor consumed by the amalgam is replenished during the lighting of the fluorescent lamp and a constant mercury vapor pressure is maintained in the discharge space, a sufficient luminous flux can be secured from the start of lighting to the extinction.

Further, the size of the effective portion of each through hole of the aggregate of fine particles is converted into a circular cross section of each through hole, the diameter is larger than the diameter of mercury atom, and the total opening area is 0.
By setting it to ² mm ² or less, after turning off the fluorescent lamp,
Mercury atoms returning to the amalgam can be concentrated near the through holes on the surface of the amalgam, and the moving speed thereof can be slowed down. As a result, the amalgam solidifies before all the mercury atoms return to the amalgam, and a large number of mercury atoms can remain in the discharge space.

The aggregate of fine particles is selected from zeolite, talc, glass powder and oxides, and the oxides are selected from titanium oxide, aluminum oxide, silicon oxide, magnesium oxide and rare earth metal oxides. By using any oxide or two or more composite oxides, the aggregate of these fine particles serves as a barrier means to limit the movement of mercury atoms, and these fine particles serve as pseudo nuclei to supercool the amalgam. Can be suppressed, and the change of the amalgam from the liquid phase to the solid phase can be facilitated.

Further, a pair of electrodes are provided at both ends of the arc tube,
By providing an amalgam near at least one of the pair of electrodes, a bulb-type fluorescent lamp with an external probe is operated, and the mercury vapor pressure in the discharge space is controlled based on the temperature distribution near the electrodes. can do.

As the base metal of the amalgam, an alloy containing at least one metal selected from bismuth, indium, tin, lead, zinc and silver, or an alloy of two or more metals selected from these. By using it, the temperature at which the amalgam should be changed from the liquid phase to the solid phase can be arbitrarily selected.

[Brief description of drawings]

FIG. 1 is a partially cutaway side view showing a structure of an arc tube in an embodiment of a fluorescent lamp of the present invention.

FIG. 2 is an enlarged cross-sectional view showing details of an amalgam 1 of the fluorescent lamp shown in FIG. 1 and an aggregate 9 of fine particle oxide adhered thereto.

3 is a diagram showing rising relative luminous fluxes in the initial stage of relighting of the fluorescent lamp of the present invention shown in FIG. 1 and the conventional fluorescent lamp shown in FIG. 4 (first conventional example).

FIG. 4 is a partially cutaway side view showing an arc tube of a fluorescent lamp of a first conventional example.

FIG. 5 is a partially cutaway side view showing an arc tube of a second conventional fluorescent lamp.

FIG. 6 is an enlarged cross-sectional view showing details of a container 10 accommodating a main amalgam 1 in the second conventional example shown in FIG.

[Explanation of symbols]

 1: Amalgam 4: Capillary tube 5: Phosphor layer 6: Arc tube 6a: Discharge space 7: Filament (electrode) 9: Aggregate of fine particles 11: Glass rod

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[Procedure amendment]

[Submission date] August 25, 1997

[Procedure amendment 1]

[Document name to be amended] Statement

[Correction target item name] 0001

[Correction method] Change

[Correction contents]

[0001]

BACKGROUND OF THE INVENTION The present invention is relates to a fluorescent lamp of containing amalgam.

[Procedure amendment 2]

[Document name to be amended] Statement

[Correction target item name] 0008

[Correction method] Change

[Correction contents]

In the case of the second conventional example, although the main amalgam 1 is stored inside the container 10,
Since substantially the entire surface of the main amalgam 1 is exposed to the discharge space 6a through the opening 10a, the surface area of the main amalgam 1 is relatively large. Therefore, after turning off the fluorescent lamp ,
Mercury atoms in the discharge electric space 6a is fed back to the main amalgam 1 in the container 10 through the opening 10a, thereby being adsorbed on the surface of the main amalgam 1. As a result, the amount of mercury atoms remaining in the discharge space 6a is extremely small. Therefore, in the initial stage of relighting of the fluorescent lamp of the second conventional example, the discharge space 6a
There is a problem in that it is difficult to maintain the mercury vapor pressure in the container at a predetermined value or higher.

[Procedure 3]

[Document name to be amended] Statement

[Correction target item name] 0018

[Correction method] Change

[Correction contents]

Next, the operating principle of the present invention will be described. During the lighting of the fluorescent lamp, the mercury atoms present in the optimum amount in the discharge space 6a start to move to the amalgam 1 as the temperature decreases after the light is turned off. However, the portion of the amalgam 1 that is in direct contact with the discharge space 6a is only the portion that faces the through holes formed in the gaps between the fine particles in the aggregate 9 of fine particles, and the total opening area thereof is 0. It is an extremely small area of 2 mm ² or less. Therefore, small conductance mercury atom transfer, a number of mercury atoms solid-reduction amalgam 1 before reaching the amalgam 1. As a result , the diffusion rate of mercury atoms into the amalgam 1 becomes extremely slow. Further, after the amalgam 1 is solidified, mercury atoms are adsorbed only on the surface of the amalgam 1 on its microscopic surface. Therefore, the mercury concentration at the interface of the amalgam 1 in contact with the discharge space 6a becomes extremely higher than that of the other parts of the amalgam 1, and the mercury vapor pressure at that part increases. As a result, a decrease in the number of mercury atoms in the discharge space 6a can be suppressed, and the initial luminous flux at the next lighting can be increased accordingly.

[Procedure amendment 4]

[Document name to be amended] Statement

[Correction target item name] 0027

[Correction method] Change

[Correction contents]

Further, the size of the effective portion of each through hole of the aggregate of fine particles is converted into a circular cross section of each through hole, the diameter is larger than the diameter of mercury atom, and the total opening area is 0.
By setting it to ² mm ² or less, the mercury atom transfer
Small cactance, many mercury atoms reach amalgam
The amalgam solidifies before it does. As a result, Amarga
The rate of diffusion of mercury atoms into the interior of the system is extremely slow.

Claims (6)

[Claims] 1. An arc tube having a phosphor layer on its inner surface,
Amalgam containing mercury provided at a predetermined position of the discharge space formed by the arc tube, and the movement of mercury atoms that reciprocate between the amalgam and the discharge space as the fluorescent lamp is turned on and off. And a barrier means for limiting, wherein the barrier means is composed of an aggregate of fine particles having a plurality of through holes attached to the surface of the amalgam, and the total opening area of the through holes of the aggregate of fine particles is the amalgam. Mercury atoms in the fluorescent lamp during lighting, it is possible to be supplied to the discharge space, and until the amalgam is solidified after the fluorescent lamp is turned off, the mercury atoms present in the discharge space returns to the amalgam A fluorescent lamp having a size capable of substantially preventing the above. 2. The size of the effective portion of each through-hole of the aggregate of fine particles has a diameter larger than the diameter of mercury atoms and a total opening area of 0.2 mm when the cross section is converted into a circle.
The fluorescent lamp according to claim 1, which has a number of ² or less. 3. The fluorescent lamp according to claim 1, wherein the aggregate of the fine particles is any one selected from zeolite, talc, glass powder and oxides. 4. The fluorescence according to claim 3, wherein the oxide is any oxide selected from titanium oxide, aluminum oxide, silicon oxide, magnesium oxide, and rare earth metal oxide, or two or more composite oxides. lamp. 5. The fluorescent lamp according to claim 1, wherein a pair of electrodes is provided at both ends of the arc tube, and the amalgam is provided in the vicinity of at least one of the pair of electrodes. . 6. The fluorescent substance according to claim 1, wherein the amalgam has a base metal made of an alloy containing at least one metal selected from bismuth, indium, tin, lead, zinc and silver. lamp.