JP3470449B2 - Cold cathode discharge lamp device, lighting device using the same, backlight, liquid crystal display device - Google Patents

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a cold cathode discharge lamp device in which a cold cathode discharge lamp having improved starting characteristics in darkness is lit at high frequency, an illuminating device using the same, a backlight, and a liquid crystal display device. Regarding

[0002]

2. Description of the Related Art In general, various discharge lamps cannot be smoothly or ionized without smooth ionization unless initial electrons that trigger discharge are present at the time of starting. The initial electrons that trigger the discharge include thermionic electrons, photoelectrons, electrons emitted by a high electric field, and electrons caused by cosmic rays in the natural world.However, the discharge lamp was left in a dark atmosphere where external light did not reach. In this case, since there are no photoelectrons, only cosmic ray electrons are present, making startup difficult. In addition, when using the lamp in a completely shielded housing or casing, even cosmic rays in the natural world often fail to reach the initial electrons. Further, in the case of starting with thermoelectrons, generally, a thermoelectron emissive substance is provided on the electrodes and heated to supply thermoelectrons, so that a heating type electrode is required and the electrode structure and the circuit structure become complicated.

In particular, a lamp using a cold cathode as an electrode has a problem that the cold cathode does not have a structure of emitting thermoelectrons at the time of starting, and therefore has a poor starting characteristic in the dark. Conventionally, in order to improve the starting characteristics of such a cold cathode discharge lamp, the electrode is provided with a radioactive isotope (RI) such as ⁶³ Ni or ¹⁴⁷ Pm, or CaO is applied to form a film to form this CaO film. Means such as emitting initial electrons by irradiating external light on the are used.

However, in the case where the radioactive isotope is provided, it is necessary to take special care in handling the radioactive isotope, and since it is necessary to seal the electrode in the form of a sealed radiation source, it takes time and labor to manufacture the electrode. However, it has the disadvantage of being expensive. On the other hand, when a CaO film is formed, electrons are not emitted without external light, so that it does not function well in complete darkness and is inferior in reliability.

From the above, the inventors of the present invention have, as described in Japanese Patent Laid-Open No. 4-121944, electron emission that emits electrons with stimulating energy below the work function in the dark inside the bulb. A discharge lamp provided with a substance (called an exo electron emitting substance) was proposed. According to such a lamp, since the exo electron emitting material made of aluminum oxide Al ₂ O ₃ or magnesium oxide MgO has a property of emitting electrons even in the dark, it is possible to trigger discharge and improve startability. Has been confirmed.

[0006]

By the way, it is generally known that when a cold cathode discharge lamp is lit at a high frequency of about 50 kHz, the luminous efficiency is improved. Therefore, even in the case of the cold cathode discharge lamp provided with the exo electron emitting material, the luminous efficiency is improved by lighting the lamp at high frequency.

However, according to the research and experiment by the inventors, the high potential side of the high frequency power supply device is connected to the cold cathode on the end side where the exo electron emitting material is provided and the cold side on the opposite side. It has been found that there is a significant difference in starting characteristics between the case of connecting to the cathode. That is, it was found that when the high potential side of the high frequency power supply device was connected to the cold cathode on the end side where the exo electron emitting material was provided, the starting characteristics were further improved.

Therefore, the present invention provides a cold cathode discharge lamp device having improved starting characteristics in a lamp provided with an exo electron emitting material that constantly emits initial electrons which triggers discharge, and a lighting device and a backlight device using the same. It is intended to provide a light and a liquid crystal display device.

[0009]

According to a first aspect of the present invention, there is provided a bulb in which an ionizing medium containing a rare gas is sealed, a cold cathode provided at least at one end of the bulb, and a cold cathode located in the bulb. A cold cathode discharge lamp provided with the cold cathode on the one end side or in the vicinity thereof, and an electron emitting substance that emits electrons with stimulating energy of a work function or less in the dark; and the cold cathode discharge lamp is connected High-frequency power for supplying high-frequency power to the cold cathode discharge lamp by connecting the cold cathode provided with the electron emitting material of the cold cathode discharge lamp or the cold cathode provided near the electron emitting material to the high potential side A cold cathode discharge lamp device comprising: a supply device;

The invention of claim 2 is the cold cathode discharge lamp device according to claim 1, characterized in that the electron emitting material is at least one of aluminum oxide and magnesium oxide.

According to a third aspect of the present invention, the electron emitting material is
The cold cathode discharge lamp device according to claim 1 or 2, wherein the cold cathode discharge lamp device is provided so as to be exposed in a discharge space.

According to the invention of claim 4, the cold cathode discharge lamp is
4. The cold cathode discharge lamp device according to claim 1, wherein the cold cathode rare gas discharge lamp is a cold cathode rare gas discharge lamp in which mercury is not sealed as an ionizing medium but only rare gas is sealed. is there.

The invention of claim 5 comprises the cold cathode discharge lamp device according to any one of claims 1 to 4; and a lighting fixture to which the cold cathode discharge lamp device is attached. It is a characteristic lighting device.

The invention of claim 6 is the cold cathode discharge lamp device according to any one of claims 1 to 4, a reflector for reflecting the light emitted from the cold cathode discharge lamp; And a diffusion / transmission means for diffusing and transmitting the light reflected by the body.

A seventh aspect of the present invention is a liquid crystal display device comprising: the backlight according to the sixth aspect; and a liquid crystal display plate illuminated by the backlight.

[0016]

According to the invention of claim 1, e provided in the valve
Since the xo electron-emitting substance has a property of emitting electrons even in the dark, it can trigger a discharge and improve the startability. Moreover, since the cold cathode provided with the exo electron emitting material or the cold cathode provided in the vicinity of the exo electron emitting material is connected to the high potential side of the high frequency power supply device, it is strong near the cold cathode at the time of starting. An electric field is generated to accelerate the electrons emitted from the exo electron emitting material. Therefore, good discharge breakdown is promoted and the startability is improved.

According to the second aspect of the present invention, since the electron emitting substance is at least one of aluminum oxide and magnesium oxide, it has excellent exo electron emitting property. According to the invention of claim 3, since the electron emitting material is exposed to the discharge space, the probability of electrons jumping into the discharge space increases,
Promotes discharge breakdown.

Since the invention of claim 4 is applied to the cold cathode rare gas discharge lamp, the startability of this type of lamp is improved. That is, since the cold cathode rare gas discharge lamp contains rare gas as an ionization medium without containing mercury, it generally has a property of poor ionization characteristics, and thus tends to be difficult to start. When the present invention is applied to such a cold cathode rare gas discharge lamp, startability is improved. According to the inventions of claims 5 to 7, it is possible to provide an illumination device, a backlight, and a liquid crystal display device, which make the most of the advantages of the cold cathode discharge lamp device.

[0019]

DESCRIPTION OF THE PREFERRED EMBODIMENTS The present invention will be described below with reference to the first embodiment shown in FIGS. FIG. 1 shows the configuration of a cold cathode discharge lamp device including a cold cathode fluorescent lamp 1 and a high frequency power supply device 2 for lighting the lamp.
Shows an exploded perspective view of a liquid crystal display device using this cold cathode discharge lamp device, and FIG. 3 shows a sectional view thereof.

The cold cathode fluorescent lamp 1 shown in FIG. 1 has an elongated bulb 10 having an outer diameter of 2.6 mm (inner diameter of 2.0 mm) and a total length of 150 mm. The bulb 10 is made of lead glass. On the inner surface of the bulb 10, the wavelength 2 of mercury is emitted.
A phosphor layer 11 made of a phosphor that is excited by 54 nm ultraviolet light to emit visible light, for example, a three-wavelength emitting phosphor is formed. The three-wavelength emission type phosphor is, for example, Y ₂ O ₃ : Eu as a red phosphor and LaP as a green phosphor.
O ₄ : Ce, Tb, BaMgAl ₁₄ O as a blue phosphor
₂₃ : Eu is used.

Cold cathodes 12a and 12b are sealed at both ends of the bulb 10 in the longitudinal direction. Cold cathode 12a, 12
b is formed by joining a rod-shaped or cylindrical electrode body 14 to the electrode shaft 13 that also serves as a lead wire, and the electrode body 14 is formed of nickel Ni. The electrode shaft 13 is connected to a sealing wire 15 made of a metal having a thermal expansion coefficient similar to that of glass, for example, a large diameter Dumet wire, and the sealing wire 15 is sealed to a sealing portion 16 at the end of the valve 10. Has been done. The sealing wires 15 are connected to external lead wires 17, respectively.

At the end of the bulb 10, one electrode 1
A layer 18 made of a substance that emits exo electrons is formed in the vicinity of 2a. The exo electron emitting material layer 18 is made of a metal oxide excellent in emitting exo electrons, and is made of, for example, at least one of aluminum oxide Al ₂ O ₃ , magnesium oxide MgO, and zinc oxide ZnO. In this embodiment, the exo electron emission material layer 18
Is used as a coating, which is formed on the inner surface of the bulb 10.

The exo electron emitting material layer 18 made of alpha alumina is mixed with, for example, butyl acetate, fine particle aluminum oxide and nitrified cotton to form a suspension, and the suspension is applied to the inner surface of the valve 10. It can be formed by firing it into a ceramic. As another method, an organic compound aluminum solution, for example, an alkoxide aluminum solution may be applied to the inner surface of the valve 10, dried, and then baked to form an alumina film.
Also, aluminum is applied to the inner surface of the valve 10 in the state of pure aluminum (Al), not in the form of oxide,
This may be oxidized by sealing the valve and heating in the exhaust process.

The exo electron emitting material layer 18 is a valve 1
It is exposed to the discharge space within 0. That is, this ex
The electron emitting material layer 18 is not covered with the phosphor layer 11. To further explain, in the case of the present embodiment, the valve 10
The phosphor layer 11 formed on the inner surface of the is peeled off at a portion facing the one electrode 12a, and the exo electron emitting material layer 18 is formed there. In this case, the exo electron emitting material layer 18 is formed up to a region higher than the height of the electrode 12a, for example, over a region of about 5 mm from the bulb end.

The valve 10 is filled with a predetermined amount of mercury and a predetermined mixed gas of argon Ar and neon Ne at a predetermined pressure as an ionizing medium. The filling pressure of the mixed rare gas is about 100 Torr.

Such a cold cathode fluorescent lamp 1 is connected to the high frequency power supply device 2 shown in FIG. 1, and is turned on by the high frequency power of about 50 kHz supplied from the high frequency power supply device 2. Has become. The high-frequency power supply device 2 may have a well-known structure, so a detailed description of the configuration will be omitted. However, for example, a high-frequency voltage of 1200 V (rms) is generated on the secondary side of the high-frequency oscillation coil 21. Has become. The high-potential-side terminal 22a of the high-frequency power supply device 2 is the cold cathode fluorescent lamp 1
It is connected to one cold cathode 12a, and the low potential side terminal 22b is connected to the other cold cathode 12a. That is, one cold cathode 12a close to the exo electron emitting material layer 18 of the cold cathode fluorescent lamp 1 is connected to the high potential side terminal 22a of the high frequency power supply device 2.

The operation of the cold cathode discharge lamp device having such a configuration will be described. From the high frequency power supply device 2 to the cold cathode fluorescent lamp 1, frequency 50 kHz, voltage 1200 V
When a high frequency voltage of about (rms) is supplied, the high frequency voltage is applied between the cold cathodes 12a and 12b provided at both ends in the cold cathode fluorescent lamp 1. Before starting, electrons are emitted toward the discharge space from the exo electron emitting material layer 18 made of alpha (α) alumina, and thus the electrons serve as a trigger for the discharge to promote the discharge destruction of the discharge space. That is, the exo electron emission material layer 18 formed on the inner surface of the bulb 10 always emits electrons without applying a high electric field even at room temperature and in the dark.
Therefore, the exo electrons serve as a trigger for the discharge, which causes discharge breakdown in the discharge space. Therefore, even when the cold cathode fluorescent lamp 1 is turned on in the space where the surroundings are shielded from cosmic rays, it is possible to promptly turn on the light.

Further, in the case of the present invention, the exo electron emitting material layer 18 is provided only on one end of the bulb 10, and one cold cathode 12a provided in the vicinity of the exo electron emitting material layer 18 is provided with the high frequency power supply device 2 described above. Since it is connected to the high potential side terminal 22a, a strong electric field is generated around the cold cathode 12a. That is, the cold cathode 12a
Is connected to the high-potential-side terminal 22a of the high-frequency power supply device 2, a large potential difference is generated between the cold cathode 12a and the valve wall close to zero potential, and a strong electric field is generated around the cold cathode 12a. Therefore, the electrons emitted from the exo electron emitting material layer 18 are further accelerated by this strong electric field and rush toward the other cold cathode 12b.

As a result, the discharge breakdown of the discharge space is further promoted, and the discharge between the cold cathodes 12a and 12b is instantly started. Therefore, even if the cold cathode fluorescent lamp 1 is used even in the dark, the starting time is greatly shortened.

In this case, since the exo electron emitting material layer 18 is exposed to the discharge space, the probability of jumping to the discharge space is high. That is, since exo electrons are slow electrons, e
When the xo electron emitting material 18 is covered with, for example, the phosphor layer 11 or the like, exo electrons are absorbed by the phosphor layer 11 and are unlikely to jump into the discharge space, and there is a concern that sufficient discharge breakdown cannot be expected. On the other hand, since the exo electron emissive material layer 18 is exposed in the discharge space, the amount of electrons jumping into the discharge space is increased and the probability of discharge breakdown is increased.

Since the exposed exo electron emitting material 18 is provided in the vicinity of the one electrode 12a,
The electrons emitted from the exo electron emitting material 18 are easily accelerated by the electric field generated around the electrode 12a which is close in distance, thereby promoting good discharge breakdown.

The results of an experiment of the cold cathode discharge lamp device shown in FIG. 1 will be described. In a lamp of the same size as the cold cathode fluorescent lamp 1 shown in FIG. 1, a fluorescent lamp (a) not provided with an exo electron emitting material 18 and an exo electron emitting material 18
When one electrode 12a close to the high frequency power supply device 2 is connected to the low potential side terminal 22b of the high frequency power supply device 2 (b), one electrode 12a close to the exo electron emitting material 18 is connected to the high potential side of the high frequency power supply device 2. When connected to terminal 22b (c
= This Example) and a starting test in the dark. For each of the lamp devices (a), (b) and (c) of each configuration, 30 samples were prepared and the average starting time of these samples was measured. In addition, each of the lamp devices (a), (b), and (c) uses a lamp with a rated lamp current of 4 mA.
After performing time aging, it was left in the room for 48 hours, left in the dark space for 1 hour before the measurement, and the starting time was measured.

As a result, in the case of the fluorescent lamp (a) not provided with the exo electron emitting material 18, the time required for starting is 10.1 seconds on average, and one electrode 12a close to the exo electron emitting material 18 is supplied with high frequency power. When connected to the low potential side terminal 22b of the supply device 2 (b), the time required for starting is 1.2 seconds on average, and one electrode 12a close to the exo electron emitting material 18 is connected to the high frequency power supply device 2 When it was connected to the high-potential side terminal 22b (c = this example), the time required for starting was 0.4 seconds on average. Therefore, it was confirmed that the cold cathode discharge lamp device of Example 1 had excellent starting characteristics.

2 and 3 show an example in which the cold cathode discharge lamp device shown in FIG. 1 is used as a light source device of a liquid crystal display device. That is, in FIGS. 2 and 3, reference numeral 30 denotes a backlight and 40 denotes a liquid crystal display panel.

The backlight 30 includes a light guide plate 31, a pair of the cold cathode fluorescent lamps 1 and 1 and reflectors 32 and 32 surrounding the fluorescent lamps 1 and 1. The light guide plate 31 is made of acrylic resin or the like. It is formed in a rectangular flat plate shape by a transparent or milky white light transmissive material such as.
The fluorescent lamps 1 and 1 are arranged at both ends of the light guide plate 31 so as to face the end faces of the light guide plate 31. The fluorescent lamps 1 and 1 are the cold cathode fluorescent lamps shown in FIG. 1, and are connected as shown in FIG. 1 to a high frequency power supply device 2 not shown in FIGS.

Each cold cathode fluorescent lamp 1, 1 is covered with a reflector 32, 32, respectively. These reflectors 32,
Reference numeral 32 is made of metal or resin, and has a substantially gutter shape whose section forms a quadratic curve and extends along the tube axis direction of the cold cathode fluorescent lamps 1, 1. Reflection surfaces 33, 33 are formed on the inner surfaces of the reflectors 32, 32 to reflect the light emitted from the fluorescent lamps 1, 1 and direct the light toward the end surface of the light guide plate 41.

A reflection plate 35 or a reflection sheet is provided on the lower surface of the light guide plate 31, that is, on the back surface. The reflection plate 35 reflects the light introduced into the light guide plate 31 and is directed to the upper surface (front surface) side. Tell A light diffusing plate 36 or a light diffusing sheet having a milky white color made of acrylic resin or the like is provided on the upper surface of the light guiding plate 31, and the light diffusing plate 36 diffuses the light emitted from the upper surface of the light guiding plate 31. Control is performed so that a uniform brightness distribution is obtained, and thereby uneven brightness is eliminated.

The backlight 30 is constructed in this way, and the liquid crystal display panel 40 is installed on the front surface of the light diffusion plate 36 of the backlight 30. Therefore, the backlight 30 and the liquid crystal display panel 40 constitute a liquid crystal display device.

In the liquid crystal display device having such a structure, when the cold cathode fluorescent lamps 1 and 1 as the light source are lit at high frequency, the light emitted from the fluorescent lamps 1 and 1 is reflected directly and by the reflectors 32 and 32. The light is reflected by the surfaces 33, 33, faces the end surface of the light guide plate 31, and enters the inside of the light guide plate 31 from this end surface. Inside the light guide plate 31, light travels while repeating total reflection on each surface, and is reflected by the reflection plate 35 provided on the back surface, so that the light is eventually emitted toward the front surface. In this way, the light traveling toward the front surface of the light guide plate 31 is diffused by the light diffusion plate 36, and the diffused light is reflected by the liquid crystal display panel 40.
Illuminate the back of the. Therefore, the liquid crystal display panel 40 is illuminated by the light from the backlight 30, and a predetermined display can be displayed on the front surface.

Such a backlight 30 includes the lamp 1
Since the starting property is good, the rise of the luminous flux after turning on the power is also good, and the rise time can be shortened even when used as a liquid crystal display device.

The reflector 32 and the cold cathode fluorescent lamp 1 constitute the illuminating device of the present invention, and the reflector 32 corresponds to a luminaire. The present invention is not limited to the above-mentioned first embodiment. That is, in the case of FIG. 1, e
Although the xo electron emitting material layer 18 and the phosphor layer 11 are formed as separate coatings, the exo electron emitting material layer 1 is formed at one end of the bulb 10.
8 may be formed, and an exo electron emitting material made of at least one of aluminum oxide Al ₂ O ₃ and magnesium oxide MgO may be further mixed in the phosphor layer 11. That is, ex formed at one end of the valve 10
In addition to the electron emitting material layer 18, exo also exists in the phosphor.
The phosphor layer 11 may be formed by mixing powder of an electron emitting substance.

In this way, since the exo electron emitting material is dispersedly provided over the entire inner surface of the bulb 10, the initial electrons are emitted over the entire discharge space,
It will be easier to create a trigger for starting.

FIG. 4 shows a second embodiment of the present invention. In this example, the exo electron emitting material layer 18 is provided over the entire inner surface of the bulb 10, and the phosphor layer 11 is laminated on the inner surface (on the discharge space side) of the exo electron emitting material layer 18. However, in this case, the phosphor layer 11 is not laminated in the region close to one cold cathode 12a side,
The exo electron emission material layer 18 is formed so as to be exposed.

Even in this case, since the exo electron emitting substance is dispersedly provided over the entire inner surface of the bulb 10, the initial electrons are emitted over the entire discharge space,
Easy to start.

FIG. 5 shows a third embodiment of the present invention. In this example, the phosphor layer 11 is formed over the entire inner surface of the bulb 10, and the exo electron emission material layer 18 is provided on the phosphor layer 11 in a region near one cold cathode 12a side. There is.

Even in this case, since the initial electrons are emitted in the vicinity of the one cold cathode 12a, the discharge breakdown is promoted,
Easy to start. FIG. 6 shows a fourth embodiment of the present invention.
In this example, an external electrode 12c extending in a strip shape along the bulb axial direction is formed on the outer surface of the bulb 10 instead of the other cold cathode 12b. Even with the cold cathode discharge lamp having such a configuration, the internal electrode 12a at one end,
Electric discharge is generated in the bulb 10 between the outer electrode 12c provided outside the bulb 10. So in this case,
An exo electron emitting material layer 18 is provided in the vicinity of the internal electrode 12a inside one end of the bulb 10, and
By connecting this internal electrode 12a to the high-potential side terminal 22b of the high-frequency power supply device 2, the same function and effect as in the first embodiment can be obtained.

FIG. 7 shows a fifth embodiment of the present invention, which is an example of a cold cathode discharge lamp having no phosphor layer 11. As a cold cathode discharge lamp having no phosphor layer 11, a cold cathode neon discharge lamp 110 is known. The cold cathode neon discharge lamp 110 of this type has a neon Ne inside the bulb 10.
The discharge gas mainly containing is not filled with mercury, and the phosphor layer 11 is not formed. The cold cathode neon discharge lamp 110 of this type tends to have a high neon encapsulation pressure in order to obtain high luminous intensity, so that the starting voltage becomes high and it takes time to start. Therefore, if the present invention is configured as shown in FIG.
Since the startability is improved as in the case of the above embodiment, the startability of the cold cathode neon discharge lamp 110 is improved. Therefore, the present invention is effective when applied to the cold cathode neon discharge lamp 110.

The discharge gas sealed in the bulb may be xenon Xe instead of neon Ne. In each of the embodiments, the case where the exo electron emitting material layer 18 is formed on the inner surface of the bulb 10 has been described. However, according to the present invention, as shown in FIG. 8, the exo electron emitting material may be directly attached to one cold cathode 12a. Good. That is, FIG. 8 shows one end of the cold cathode discharge lamp, and one cold cathode 12a sealed at one end of the bulb 10 has an electrode body 14 made of a nickel sleeve. The internal space of the electrode body 14 is filled with a getter 50 made of an alloy of zirconium Zr and aluminum Al and an amalgam made of mercury and titanium, and an exo electron emitting material layer 18 is provided near the opening. There is.

Then, the cold cathode 12a having such an exo electron emitting material layer 18 is used as an electrode shaft 13 and a sealing wire 15.
And high frequency power supply device 2 via the external lead wire 17
Is connected to the high potential side terminal 22b.

Even with such a structure, electrons are emitted from the exo electron emitting material layer 18 toward the discharge space in the vicinity of one cold cathode 12a, and this electron triggers the discharge. Since one cold cathode 12a provided with the exo electron emitting material layer 18 is connected to the high potential side terminal 22a of the high frequency power supply device 2, this cold cathode 12a
A strong electric field is generated around a, so that e
The electrons emitted from the xo electron emissive material layer 18 are further accelerated by this strong electric field. As a result, the discharge breakdown of the discharge space is promoted, and the cold cathodes 12a, 1
The discharge between 2b is started. The cross-sectional shape of the valve may be circular, elliptical or oval.

[0051]

As described above, according to the first aspect of the invention, the exo electron emitting substance provided in the bulb emits electrons, so that not only does this trigger an electric discharge, but this exo electron emitting substance is also generated. Provided cold cathode or ex
Since the cold cathode provided close to the electron emitting material was connected to the high potential side of the high frequency power supply device, a strong electric field was generated in the vicinity of this cold cathode at the time of starting and was emitted from the exo electron emitting material. It will accelerate the electrons. Therefore, the discharge breakdown of the discharge space is promoted, the main discharge between both electrodes is quickly generated, and the startability is improved.

According to the second aspect of the present invention, since the electron emitting substance is at least one of aluminum oxide and magnesium oxide, it has an excellent exo electron emitting property. According to the invention of claim 3, since the electron emitting material is exposed to the discharge space, the probability of electrons jumping into the discharge space increases,
Promotes discharge breakdown.

Since the invention of claim 4 is applied to the cold cathode rare gas discharge lamp, the startability of this type of lamp is improved. That is, since the cold cathode rare gas discharge lamp does not contain mercury as an ionization medium but contains a rare gas, it generally has a property of poor ionization characteristics, and thus tends to be difficult to start. When the present invention is applied to such a cold cathode xenon rare gas discharge lamp, startability is improved. Claims 5 to 7
According to the invention, it is possible to provide an illuminating device, a backlight, and a liquid crystal display device that take advantage of the advantages of the cold cathode discharge lamp device.

[Brief description of drawings]

FIG. 1 is a diagram showing a configuration of a cold cathode discharge lamp device including a cold cathode fluorescent lamp and a high frequency power supply device according to a first embodiment of the present invention.

FIG. 2 is an exploded perspective view of a liquid crystal display device using the cold cathode discharge lamp device.

FIG. 3 is a cross-sectional view of the liquid crystal display device of the same embodiment.

FIG. 4 is a diagram showing a configuration of a cold cathode discharge lamp device showing a second embodiment of the present invention.

FIG. 5 is a diagram showing a configuration of a cold cathode discharge lamp device showing a third embodiment of the present invention.

FIG. 6 is a diagram showing a configuration of a cold cathode discharge lamp device showing a fourth embodiment of the present invention.

FIG. 7 is a diagram showing a configuration of a cold cathode discharge lamp device showing a fifth embodiment of the present invention.

FIG. 8 is a sectional view of one end of a cold cathode discharge lamp showing a sixth embodiment of the present invention.

[Explanation of symbols]

1 ... Cold cathode fluorescent lamp 2. High frequency power supply device 10 ... Valve 11 ... Phosphor layer 12a, 12b ... Cold cathode 18 ... exo electron-emitting material layer 21 ... High frequency oscillation coil 22a ... High potential side terminal 22b ... Low potential side terminal 30 ... Backlight 31 ... Light guide plate 32 ... Reflector 33 ... Reflective surface 35 ... Reflector 36 ... Light diffuser 40 ... Liquid crystal display panel

─────────────────────────────────────────────────── ─── Continuation of the front page (56) References JP-A-5-6758 (JP, A) JP-A-5-28961 (JP, A) JP-A-6-275237 (JP, A) (58) Field (Int.Cl. ⁷ , DB name) H01J 61/04 H01J 61/06 H01J 61/54 H01J 61/35 H01J 61/78

Claims (7)

(57) [Claims] 1. A bulb in which an ionizing medium containing a rare gas is sealed, a cold cathode provided inside at least one end of the bulb, and a cold cathode at the one end located inside the bulb or in the vicinity thereof. A cold cathode discharge lamp, which is provided in the dark and emits electrons with stimulating energy below a work function; and a cold cathode discharge lamp connected to the cold cathode discharge lamp; Or a high frequency power supply device for supplying high frequency power to the cold cathode discharge lamp by connecting the cold cathode provided with the cold cathode or the cold cathode provided in the vicinity of the electron emitting material to the high potential side. Cold cathode discharge lamp device. 2. The cold cathode discharge lamp device according to claim 1, wherein the electron emitting material is at least one of aluminum oxide and magnesium oxide. 3. The cold cathode discharge lamp device according to claim 1, wherein the electron emitting material is provided so as to be exposed in a discharge space. 4. The cold cathode discharge lamp according to claim 1, wherein the cold cathode discharge lamp is a cold cathode rare gas discharge lamp in which mercury is not enclosed as an ionizing medium and only a rare gas is enclosed. The cold cathode discharge lamp device as described in 1. 5. A lighting device comprising: the cold cathode discharge lamp device according to claim 1; and a lighting fixture to which the cold cathode discharge lamp device is attached. . 6. A cold cathode discharge lamp device according to claim 1, a reflector for reflecting light emitted from the cold cathode discharge lamp, and a reflector for reflecting the light emitted from the cold cathode discharge lamp. And a diffuse transmission means for diffusing and transmitting light. 7. A liquid crystal display device comprising: the backlight according to claim 6; and a liquid crystal display plate illuminated by the backlight.