JPH0729550A - Variable color discharge lamp - Google Patents

Abstract

PURPOSE:To enable toning over a wide range while securing light emitting intensity large in a variable color discharge lamp to mix light emitting colors of a fluorescent material and a negative glow together. CONSTITUTION:Mercury vapor and noble gas are sealed in a bulb 1, and a fluorescent material 4 is applied to an inner peripheral surface of a tube wall. A pair of main electrodes 2 are arranged outside of both end parts in the lengthwise direction of the bulb 1, and auxiliary electrodes 3 are arranged separately from each other in the diameter direction inside of the bulb 1. When discharge is caused between the main electrodes 2, the fluorescent material 4 emits light by receiving ultraviolet radiation generated by excitation of the mercury vapor. When discharge is caused between the auxiliary electrodes 3, light emission of a negative glow is generated by the noble gas. Since the main electrodes 2 are arranged outside of the bulb 1 and the auxiliary electrodes 3 are arranged inside of the bulb 1, the difference between light emitting intensity of the fluorescent material 4 and light emitting intensity of the negative glow can be reduced.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention mixes the luminescent color of a fluorescent substance with the luminescent color of a negative glow for one bulb, and changes the intensity of both luminescent colors to make toning variable. The present invention relates to a color discharge lamp.

[0002]

2. Description of the Related Art The inventor of the present invention has previously proposed a variable color discharge lamp of this type having the structure shown in FIG. That is, mercury vapor and a rare gas as light emitting gases are enclosed in the straight tube-shaped bulb 1, and the fluorescent substance 4 is formed on the inner peripheral surface of the bulb 1 of the bulb 1.
A pair of main electrodes 2 are disposed inside the bulb 1 at both ends in the longitudinal direction of the bulb 1, and the outer peripheral surface of the bulb 1 has a surface including the center line of the bulb 1. A pair of auxiliary electrodes 3 are arranged so as to face each other with the pair of electrodes sandwiched therebetween. The auxiliary electrode 3 is formed of a transparent conductive film such as an ITO film, and is provided over substantially the entire length of the bulb 1 in the longitudinal direction. The distance L ₁ between the main electrodes 2 is set to such an extent that a positive column is formed in most of the region of the bulb 1 when discharging between the main electrodes 2, and the distance L ₂ between the auxiliary electrodes 3 is The length is set to not more than twice the length of the negative glow formed between the electrodes that are sufficiently separated to form the pillar. Therefore, when a discharge is generated between the auxiliary electrodes 3, a negative glow is generated in a region of about half the tube diameter of the bulb 1.

An alternating voltage is applied from the main lighting circuit 5 between the main electrodes 2. Mercury vapor is excited by the arc discharge generated between the main electrodes 2 and ultraviolet rays are emitted. This ultraviolet ray is converted into visible light by the fluorescent substance 4. Further, an alternating voltage is applied between the auxiliary electrodes 3 from the auxiliary lighting circuit 6, and light emission due to a rare gas occurs in the negative glow of the discharge generated between the auxiliary electrodes 3. The auxiliary electrode 3 is formed over substantially the entire length of the bulb 1 in the longitudinal direction, the distance L ₂ between the auxiliary electrodes 3 is set to not more than twice the length of the negative glow, and the auxiliary electrodes 3 are alternately arranged. Since the voltage is applied, the emission color of the negative glow can be taken out over almost the entire area of the internal space of the bulb 1, and the emission color of the fluorescent substance 4 and the emission of the negative glow can be obtained over the almost entire area of the bulb 1. It is possible to mix the emission colors. As a result, if the emission color of the fluorescent substance 4 and the emission color of the rare gas in the negative glow are made different, the emission intensity of the fluorescent substance 4 due to the discharge between the main electrodes 2 and the emission intensity between the auxiliary electrodes 3 occur. By adjusting the ratio of the negative glow to the emission intensity, the emission color of the bulb 1 obtained as a mixture of both emission colors can be adjusted.

For example, if calcium halophosphate that absorbs ultraviolet rays and converts it into white light is mainly used as the fluorescent substance 4 and neon that emits red light in a negative glow is used as a rare gas, white light and red light can be obtained. Mixed color light is obtained. Further, the emission intensity of the white light and the red light changes by changing the ratio of the applied voltage between the main electrode 2 and the auxiliary electrode 3, so that the mixed color light can be changed between white and red. Of.

[0005]

In the variable color discharge lamp described above, the main electrode 2 is provided outside the bulb 1, and the auxiliary electrode 3 is provided inside the bulb 1. The mercury vapor is sufficiently excited by the discharge between the electrodes 2, but the discharge between the auxiliary electrodes 3 is significantly weaker than the discharge between the main electrodes 2, so that the light emission by neon is a fluorescent substance by the mercury vapor. It becomes much weaker than the light emission of 4. That is, since red light has an extremely small emission intensity as compared to white light, if the maximum brightness is set at both ends of the toning range when toning is performed over the entire range from white to red, The emission intensity on the red side is smaller than that on the white side, and there is a problem in that the emission intensity cannot be kept constant and toning is impossible. On the contrary, if you try to adjust the light emission intensity over the entire range while keeping the light emission intensity constant, the light emission intensity of the mixed color light will be restricted to the maximum intensity of red light, and the light amount will decrease and The problem that the range becomes narrow arises. Further, if the emission intensity is set to be higher than the maximum intensity of red light, the mixed light is biased to the white side, and it becomes difficult to adjust the color to the red side, which causes a problem that the toning range is narrowed.

An object of the present invention is to solve the above problems, and an object of the present invention is to provide a variable color discharge lamp capable of toning over a wide range while maintaining a high emission intensity. Is.

[0007]

The invention according to claim 1 is the first
Of a light emitting gas and a second light emitting gas, the bulb having a fluorescent substance, at least a pair of main electrodes for generating a discharge in the bulb for exciting the first light emitting gas to emit light, and the main electrode At least one pair of auxiliary electrodes that generate a negative glow in the bulb that causes the second light-emitting gas to emit light through a discharge path different from the discharge by the fluorescent substance. A variable color discharge lamp that converts light into light and mixes visible light from a second light emitting gas, which has an emission color different from that of the fluorescent substance, with visible light emitted from the fluorescent substance, and includes a main electrode Is provided outside the bulb, and the auxiliary electrode is provided inside the bulb.

According to a second aspect of the invention, a bulb provided with a fluorescent substance in which the first light emitting gas and the second light emitting gas are enclosed, and a discharge for exciting the first light emitting gas to emit light are provided in the bulb. At least one pair of main electrodes for generating a negative glow that causes the second light emitting gas to emit light in the bulb in a discharge path different from the discharge by the main electrode. The light emitted from the emitting gas is converted into visible light by the fluorescent substance, and the visible light from the second light emitting gas, which has an emission color different from the emission color of the fluorescent substance, is exchanged with visible light emitted from the fluorescent substance. A variable color discharge lamp that mixes colors is characterized in that both a main electrode and an auxiliary electrode are provided inside a bulb.

According to a third aspect of the invention, a bulb provided with a fluorescent material in which a first light emitting gas and a second light emitting gas are enclosed, and a discharge for exciting the first light emitting gas to emit light are provided in the bulb. At least one pair of main electrodes for generating a negative glow that causes the second light emitting gas to emit light in the bulb in a discharge path different from the discharge by the main electrode. The light emitted from the emitting gas is converted into visible light by the fluorescent substance, and the visible light from the second light emitting gas, which has an emission color different from the emission color of the fluorescent substance, is exchanged with visible light emitted from the fluorescent substance. A variable color discharge lamp that mixes colors, characterized in that both the main electrode and the auxiliary electrode are provided outside the bulb.

The invention of claim 4 is characterized in that, in the invention of claim 1 or 3, an alternating voltage of 1 to 50 MHz is applied to the main electrode.

[0011]

According to the structure of the present invention, the main electrode is provided outside the valve and the auxiliary electrode is provided inside the valve, so that the main electrode is provided inside the valve and the auxiliary electrode is provided outside the valve. Compared with the conventional configuration, the discharge between the auxiliary electrodes is relatively strengthened with respect to the discharge between the main electrodes, and the emission intensity of the second light-emitting gas in the negative glow is changed to the emission intensity of the fluorescent substance. Can be strengthened relative to.
As a result, it is possible to reduce the difference between the emission intensity of the fluorescent substance and the emission intensity of the negative glow, and to increase the maximum emission intensity of the negative glow. Color is possible.

According to the structure of claim 2, by providing both the main electrode and the auxiliary electrode inside the valve,
Compared to the conventional configuration, it is possible to enhance the discharge between the auxiliary electrodes, reduce the difference between the emission intensity of the fluorescent substance and the emission intensity of the negative glow, and increase the maximum intensity of emission in the negative glow, It is possible to adjust colors over a wide range while securing a relatively high emission intensity.

According to the third aspect of the invention, since the main electrode and the auxiliary electrode are both provided outside the valve,
As compared with the conventional configuration, the discharge between the main electrodes is weakened, and the difference in emission intensity between the fluorescent substance and the negative glow can be reduced. That is, it becomes easy to balance the emission intensity of the fluorescent substance and the emission intensity of the negative glow, and toning becomes easy.

According to the structure of claim 4, in the structure in which the main electrode is provided outside the valve, an alternating voltage of 1 to 50 MHz is applied to the main electrode, so that the main electrode is not provided in the valve. Even with this configuration, it is possible to excite the first light emitting gas by causing high-frequency discharge in the bulb.

[0015]

【Example】

(Embodiment 1) As shown in FIG. 1, a valve 1 is a straight tube, and a pair of main electrodes 2 are arranged on the outer surfaces of both ends in the longitudinal direction, and the valve 1 is provided at an intermediate portion in the longitudinal direction of the valve 1.
A pair of auxiliary electrodes 3 are arranged inside the bulb 1 so as to be spaced apart from each other in the radial direction. The distance L ₂ between the auxiliary electrodes 3 is set to be equal to or less than twice the length of the negative glow formed between the electrodes sufficiently separated to generate the positive column, and the distance L ₁ between the main electrodes 2 is set.
Is set to be longer than the distance L ₂ between the auxiliary electrodes 3.
The fluorescent material 4 is applied to the inner peripheral surface of the bulb wall of the bulb 1, and the bulb 1 is filled with mercury vapor as the first light emitting gas and rare gas as the second light emitting gas. There is. In this embodiment, the fluorescent substance 4 mainly contains calcium halophosphate, and the fluorescent substance 4 absorbs ultraviolet rays and emits white light. Further, neon gas that emits red light in the negative glow is used as the rare gas.

A main lighting circuit 5 is provided between the main electrodes 2 to
An alternating voltage of 50 MHz is applied, and mercury vapor is excited by the high frequency discharge generated between the main electrodes 2. Since ultraviolet rays are emitted when the mercury vapor is excited, the fluorescent substance 4 is irradiated with ultraviolet rays, and as a result, the fluorescent substance 4 emits white light. On the other hand, an alternating voltage is applied between the auxiliary electrodes 3 by the auxiliary lighting circuit 6, and the rare gas emits light and red light is emitted in the negative glow generated between the auxiliary electrodes 3. Here, the distance L ₂ between the auxiliary electrodes 3 is set to be equal to or less than twice the length of the negative glow, and an alternating voltage is applied between the auxiliary electrodes 3, so that the distance between the auxiliary electrodes 3 is substantially the same. The negative glow can be formed as a result, and the emission color from the negative glow can be taken out over a wide range in the bulb 1. Therefore, the mixed color light of the emission color of the fluorescent substance 4 and the emission color of the negative glow can be taken out from the bulb 1. The ratio of the emission intensity of white light and red light is
It can be changed by changing the ratio of the applied voltage between the main electrode 2 and the applied voltage between the auxiliary electrodes 3, and the mixed color light can be changed between white and red.

In the above structure, the main electrode 2 is provided outside the bulb 1, so that the discharge between the main electrodes 2 is weakened as compared with the conventional configuration in which the main electrode 2 is provided inside the bulb 1. Since the auxiliary electrode 3 is provided inside the bulb 1, the discharge between the auxiliary electrodes 3 is enhanced as compared with the conventional configuration in which the auxiliary electrode 3 is provided outside the bulb 1. In short, the emission intensity of the negative glow can be increased with respect to the emission intensity of the fluorescent substance 4 to reduce the difference in emission intensity between the fluorescent substance 4 and the negative glow. Moreover, since the emission intensity of the red light due to only the negative glow is increased, it is possible to perform color adjustment over a wide range with the emission intensity of the mixed color light being higher than that of the conventional configuration. In addition, as a result of the increased emission intensity of the mixed color light, the dimming range for the same color also becomes wider.

In order to facilitate the starting of the discharge between the main electrodes 2, the distance L ₁ ′ between the main electrodes 2 may be made smaller than the distance L ₁ shown in FIG. 1 as shown in FIG. 2 ( L ₁ ′ <
L ₁ ). Further, as the output frequency of the main lighting circuit 5, for example, a legal frequency of 13.56 MHz can be selected. (Embodiment 2) In this embodiment, as shown in FIG. 3, an example is shown in which both the main electrode 2 and the auxiliary electrode 3 are arranged inside the bulb 1. A hot cathode is used for both the main electrode 2 and the auxiliary electrode 3. The distance between the main electrodes 2 is set so that a positive column is formed in most of the bulb 1 in the longitudinal direction, and an alternating voltage (a frequency lower than that in the first embodiment is sufficient) is applied between the main electrodes 2. . Other configurations are similar to those of the first embodiment.

The configuration of the present embodiment is different from the conventional configuration in that the auxiliary electrode 3 is provided inside the bulb 1. Therefore, the emission intensity of the negative glow is increased as compared with the conventional configuration. You can That is, if neon is used as the rare gas, the maximum intensity of emission of red light is increased, and it is possible to adjust the color over a wide range while increasing the emission intensity of the mixed color light as a whole. In addition, the use of hot cathodes for both the main electrode 2 and the auxiliary electrode 3 facilitates the start of discharge.

(Embodiment 3) In this embodiment, as shown in FIG. 4, an example is shown in which both the main electrode 2 and the auxiliary electrode 3 are arranged inside the bulb 1. That is, the main electrode 2 has the same configuration as that of the first embodiment, and the auxiliary electrode 3 has the same configuration as the conventional configuration. Other configurations are similar to those of the first embodiment.

The configuration of the present embodiment is different from the conventional configuration in that the main electrode 2 is provided outside the bulb 1. Compared with the conventional configuration, the excitation probability of mercury vapor is reduced and the fluorescent substance 4 of the fluorescent substance 4 is reduced. The emission intensity can be reduced. Therefore, the emission intensity of the fluorescent substance 4 becomes relatively smaller than the emission intensity of the negative glow, and even if the emission intensity is set to the maximum side in the dimming range, there is little bias in the emission color of the fluorescent substance 4. As a result, it is possible to adjust the color over a relatively wide range. Moreover, since the main electrode 2 and the auxiliary electrode 3 are both provided outside the bulb 1, the main electrode 2 and the auxiliary electrode 3 are not consumed and the life is extended.

(Embodiment 4) In this embodiment, as shown in FIG.
In the structure of the third embodiment, the distance L ₁ ′ between the main electrodes 2 is set to be approximately the same as the distance L ₂ between the auxiliary electrodes 3 (L
_{1 '≒ L 2 <L 1} ). That is, the distance between the main electrodes 2 is also set to not more than twice the length of the negative glow formed between the electrodes that are sufficiently separated to form a positive column. In this configuration, the voltage and frequency of the voltage applied between the main electrodes 2 are set so that a discharge sufficient to excite the mercury vapor is generated, and a negative glow is formed to allow the rare gas to emit light. . In this case, since negative glow is also generated by the discharge between the main electrodes 2, the emission intensity due to the negative glow can be increased as compared with the conventional configuration in which the negative glow is formed only between the auxiliary electrodes 3, and the main electrode 2 In addition to the fact that it is provided outside the bulb 1, it is possible to reduce the difference in emission intensity between the fluorescent substance 4 and the negative glow. That is, it is possible to adjust the color over a wide range while increasing the emission intensity of the mixed color light.

Further, in the configuration of this embodiment, if the output voltage and the output frequency of the auxiliary lighting circuit 6 are set so as to generate discharge that excites mercury vapor together with the negative glow between the auxiliary electrodes 3, the fluorescent substance 4 will be emitted. The emission intensity can be increased, and the maximum value of the emission intensity can be increased. (Embodiment 5) As shown in FIG. 6, this embodiment shows an example in which a main electrode 2a is added inside both ends of the bulb 1 in the longitudinal direction of the structure of the embodiment 3 shown in FIG. That is,
In contrast to the conventional configuration, the main electrode 2 is added to the outside of the bulb 1. The output voltage of the main lighting circuit 5a provided separately from the main lighting circuit 5 is applied to the main electrode 2a.

In this structure, the discharge between the main electrodes 2a is stronger than the discharge between the main electrodes 2, so that which of the main electrodes 2 and 2a is emitted depending on the desired intensity of the emission of the fluorescent substance 4. It is possible to select whether to perform the discharge between them. Therefore, it becomes possible to change the emission intensity of the mixed color light over a wide range. This configuration is particularly effective when the color temperature is adjusted by mixing the emission color of the negative glow with the emission color of the fluorescent substance 4, and the range of adjustment of the emission intensity is expanded as compared with the conventional configuration. You can

(Sixth Embodiment) As shown in FIG. 7, this embodiment shows an example in which an auxiliary electrode 3a is added to the outside of the valve 1 in addition to the structure of the second embodiment shown in FIG. That is, as compared with the conventional configuration, the auxiliary electrode 3 is provided inside the bulb 1.
Is added. The output voltage of the auxiliary lighting circuit 6a is applied to the auxiliary electrode 3a separately from the auxiliary lighting circuit 6.

In this structure, the emission intensity of the auxiliary electrode 3a can be made smaller than that of the auxiliary electrode 3 for the negative glow, so that the emission intensity of the negative glow can be varied over a wide range. As a result, the emission intensity of the mixed color light can be increased to perform a wide range of color adjustment, and the wide range of color adjustment can be performed only by adjusting the emission intensity of the negative glow.

(Embodiment 7) As shown in FIG. 8, this embodiment shows a combination of the construction of Embodiment 2 shown in FIG. 3 and the construction of Embodiment 3 shown in FIG. That is, compared to the conventional configuration, the main electrode 2 is added to the outside of the valve 1,
It has a configuration in which an auxiliary electrode 3 is added inside the bulb 1. In short, the main electrodes 2 and 2a and the auxiliary electrodes 3 and 3a are provided inside and outside the bulb 1, respectively, and the main electrode 2a has a main lighting circuit 5a provided separately from the main lighting circuit 5. The output voltage is applied, and the output voltage of the auxiliary lighting circuit 6a provided separately from the auxiliary lighting circuit 6 is applied to the auxiliary electrode 3a.

With this structure, the range of adjusting the emission intensity of the fluorescent substance 4 and the negative glow is widened, and the mixed color light can be adjusted over a wide range. That is, when the emission intensity is set low, the main electrode 2 and the auxiliary electrode 3a provided outside the bulb 1 are used, and when the emission intensity is set high, the main electrode 2 provided inside the bulb 1 is used.
It suffices to use a and the auxiliary electrode 3.

(Embodiment 8) In this embodiment, as shown in FIG. 9, the auxiliary electrode 3 has the same structure as the embodiment 2 shown in FIG.
It uses a cold cathode. Other configurations are similar to those of the second embodiment. Further, not only the second embodiment but also any of the above-mentioned embodiments, the cold cathode can be adopted for the main electrodes 2 and 2a and the auxiliary electrode 3 for the electrodes provided inside the bulb 1.

(Embodiment 9) In this embodiment, as shown in FIG. 10, the auxiliary electrode 3 is divided into two in the longitudinal direction of the bulb 1 with respect to the structure of the embodiment 3 shown in FIG. That is, two pairs of auxiliary electrodes 3 are provided, and the output voltage of the separately provided auxiliary lighting circuit 6 is applied between each pair of auxiliary electrodes 3.

The number of divisions of the auxiliary electrode 3 may be three or more divisions instead of two divisions. Further, the auxiliary lighting circuit 6 does not necessarily have to be separately provided for each pair of auxiliary electrodes 3, and the output voltage of one auxiliary lighting circuit 6 may be applied to each pair of auxiliary electrodes 3. The structure in which the auxiliary electrode 3 is divided in this way can be adopted in the other embodiments described above other than the structure of the third embodiment.

In each of the above embodiments, neon is used as the rare gas, but other light emitting gas may be used, or two or more kinds of gas may be mixed and used. The first light emitting gas and the fluorescent substance 4 are not limited to those in the above embodiment.

[0033]

According to the invention of claim 1, since the main electrode is provided outside the valve and the auxiliary electrode is provided inside the valve,
As compared with the conventional configuration, the discharge between the auxiliary electrodes is relatively strengthened with respect to the discharge between the main electrodes, and the emission intensity of the second light emitting gas in the negative glow is compared with the emission intensity of the fluorescent substance. Can be relatively strengthened by reducing the difference between the emission intensity of the fluorescent substance and the emission intensity of the negative glow, and the maximum emission intensity of the negative glow can be increased to secure a relatively large emission intensity. However, there is an advantage that it is possible to adjust colors over a wide range.

According to the second aspect of the invention, since the main electrode and the auxiliary electrode are both provided inside the bulb, the discharge between the auxiliary electrodes can be intensified as compared with the conventional structure, and the emission intensity of the fluorescent substance can be improved. There is an advantage that the difference with the emission intensity of the negative glow can be reduced and the maximum intensity of the emission of the negative glow can be increased, and toning over a wide range while securing a relatively large emission intensity. .

According to the third aspect of the present invention, since the main electrode and the auxiliary electrode are both provided outside the bulb, the discharge between the main electrodes is weakened as compared with the conventional structure, and the fluorescent substance and the negative glow are generated. The difference in the emission intensity of can be reduced,
There is an advantage that it becomes easier to balance the emission intensity of the fluorescent substance and the emission intensity of the negative glow, and the color adjustment becomes easy. The invention of claim 4 applies an alternating voltage of 1 to 50 MHz to the main electrode with respect to the structure in which the main electrode is provided outside the valve. Therefore, while the main electrode has no electrode inside the valve, There is an effect that a high frequency discharge can be generated in the bulb to excite the first light emitting gas.

[Brief description of drawings]

FIG. 1 is a schematic configuration diagram illustrating a first embodiment.

FIG. 2 is a schematic configuration diagram showing another example of the first embodiment.

FIG. 3 is a schematic configuration diagram showing a second embodiment.

FIG. 4 is a schematic configuration diagram showing a third embodiment.

FIG. 5 is a schematic configuration diagram showing a fourth embodiment.

FIG. 6 is a schematic configuration diagram showing a fifth embodiment.

FIG. 7 is a schematic configuration diagram showing a sixth embodiment.

FIG. 8 is a schematic configuration diagram showing a seventh embodiment.

FIG. 9 is a schematic configuration diagram showing an eighth embodiment.

FIG. 10 is a schematic configuration diagram showing a ninth embodiment.

FIG. 11 is a schematic configuration diagram showing a conventional example.

[Explanation of symbols]

 1 bulb 2 main electrode 3 auxiliary electrode 4 fluorescent substance 5 main lighting circuit 6 auxiliary lighting circuit

Claims (4)

[Claims] 1. A bulb provided with a fluorescent material in which a first light emitting gas and a second light emitting gas are enclosed, and at least a pair for generating a discharge in the bulb for exciting the first light emitting gas to emit light. Of the first light emitting gas, and at least a pair of auxiliary electrodes for generating in the bulb a negative glow that causes the second light emitting gas to emit light in a discharge path different from the discharge by the main electrode. Variable light emission that converts the emitted light into visible light by the fluorescent substance and mixes the visible light from the second light emitting gas, which is an emission color different from the emission color of the fluorescent substance, with the visible light emitted from the fluorescent substance. A variable color discharge lamp, which is an electric lamp, wherein a main electrode is provided outside the bulb and an auxiliary electrode is provided inside the bulb. 2. A bulb provided with a fluorescent material in which a first light emitting gas and a second light emitting gas are enclosed, and at least a pair for generating a discharge in the bulb for exciting the first light emitting gas to emit light. Of the first light emitting gas, and at least a pair of auxiliary electrodes for generating in the bulb a negative glow that causes the second light emitting gas to emit light in a discharge path different from the discharge by the main electrode. Variable light emission that converts the emitted light into visible light by the fluorescent substance and mixes the visible light from the second light emitting gas, which is an emission color different from the emission color of the fluorescent substance, with the visible light emitted from the fluorescent substance. A variable color discharge lamp, which is an electric lamp in which both a main electrode and an auxiliary electrode are provided inside a bulb. 3. A bulb provided with a fluorescent material in which a first light emitting gas and a second light emitting gas are enclosed, and at least one pair for generating a discharge in the bulb for exciting the first light emitting gas to emit light. Of the first light emitting gas, and at least a pair of auxiliary electrodes for generating in the bulb a negative glow that causes the second light emitting gas to emit light in a discharge path different from the discharge by the main electrode. Variable light emission that converts the emitted light into visible light by the fluorescent substance and mixes the visible light from the second light emitting gas, which is an emission color different from the emission color of the fluorescent substance, with the visible light emitted from the fluorescent substance. A variable color discharge lamp, which is an electric lamp in which both a main electrode and an auxiliary electrode are provided outside a bulb. 4. An alternating voltage of 1 to 50 MHz is applied to the main electrode, according to claim 1 or claim 3.
Variable color discharge lamp described.