JPS63313461A - Electrodeless discharge lamp - Google Patents

Abstract

PURPOSE:To prevent a discharge lamp from being increased in its external size as well as preventing its shield body from being seen from the outside so that a sufficient shielding effect may be realized by arranging the shield body inside an external bulb provided with a phosphor layer. CONSTITUTION:Ultraviolet rays radiated form an internal bulb 1 pass through the mesh of a shield body 9 and are converted in rays of white light on a phosphor layer 5 serving as a coating over the inner periphery of an external bulb 3. Then, partial ultraviolet rays are intercepted by a shield body 9 to form an area of shade but the rest are dispersed by a phosphor layer 5. Therefore, a lamp can radiate rays of visual light with even brightness as a whole. In addition, its appearance looks better because the shield body 9 including meshes is arranged inside the external bulb 3 and can not be seen from the outside due to interception by the phosphor layer 5. Furthermore, the total shape thereof may not be enlarged because the shield body 9 is not arranged outside the external bulb 3. An electrodeless discharge lamp having high shielding effect for electromagnetic radiation and an excellent appearance with its small size can be obtained in this way.

Description

[Detailed Description of the Invention] [Technical Field] The present invention has no filament electrode and converts ultraviolet rays emitted when a low-pressure discharge gas is inductively discharged using a high-frequency electromagnetic field into visible light using a phosphor. This invention relates to an electrodeless discharge lamp.

[Background Art] Conventionally, fluorescent lamps have been provided in which mercury atoms are excited by arc discharge to emit ultraviolet rays, and visible light is obtained by irradiating a phosphor layer with the ultraviolet rays. Fluorescent lamps have relatively short lifetimes and low efficiency. To solve this problem, electrodeless discharge lamps with longer lifespan and higher efficiency have been proposed for about 10 years, and are disclosed in, for example, Japanese Patent Laid-Open No. 78766/1983. By the way, this type of electrodeless discharge lamp is
By applying a high-frequency electromagnetic field to excite low-pressure gas atoms and inductively discharging them, ultraviolet and visible light are emitted, and the ultraviolet light is converted into visible light by irradiating the phosphor layer. As a matter of principle, this includes the problem of radiating high frequencies to the outside and causing radio wave interference to external equipment. Therefore, an electromagnetic shield is essential to prevent radio wave Fl damage in the surrounding area.

Conventionally, as shown in FIG. 2, such an electromagnetic shield covers the entire lamp A with a shield body 9 made of a metal mesh through which the light rays emitted from the lamp A can pass, or As shown in the figure, there was a lamp A in which a transparent conductive film 1o was formed on the bulb surface. However, in the former configuration, the shield body 9 is located outside the lamp A.
Since the shield body 9' is disposed, there is a problem that the overall size becomes large, and the mesh of the shield body 9' is directly exposed, resulting in an unsightly appearance. However, since the visible light rays emitted from the lamp A pass through the mesh of the shield body 9', there is a problem in that a shadow is formed by the shield body 9', resulting in uneven brightness. Further, in the latter definition, forming the transparent conductive film 10 on a bulb that is not planar requires a relatively complicated process, resulting in high costs. Furthermore, in order to suppress noise to a practical level, it is necessary to set the resistance value to be sufficiently smaller (filΩ/cm2 or less) than the resistance value normally obtained with transparent conductive films (97 cm" or more). Generally, when trying to reduce the resistance value, the transparency decreases, so the current level of technology for forming transparent conductive N!lX cannot sufficiently suppress radio wave radiation.In the end, the former configuration appearance, size,
Since there are problems such as brightness unevenness, and the latter structure has problems such as the effect of suppressing electromagnetic radiation, it cannot be said that the structure is satisfactory in any case, and therefore, a better structure has been required.

[Object of the Invention] The present invention has been made in view of the above-mentioned points, and its purpose is to provide a system that provides a powerful electromagnetic radiation shielding effect.
Another object of the present invention is to provide an electrodeless discharge lamp that is compact and has an excellent appearance.

DISCLOSURE OF THE INVENTION 1 (Structure) The electrodeless discharge lamp according to the present invention has an inner bulb filled with a discharge gas, and a high-frequency current output from a power oscillation section is applied to generate a high-frequency electromagnetic field in the discharge gas in the inner bulb. The inner bulb has a phosphor layer on its periphery that converts the ultraviolet rays emitted when the discharge gas is inductively discharged by the electromagnetic field into visible light. An outer bulb is placed around the bulb, and an outer bulb is placed outside the induction coil and inside the phosphor layer to surround the induction coil to block the electromagnetic field generated by the induction coil from leaking to the outside. At the same time, it consists of a shield body made of a metal mesh that allows most of the ultraviolet rays emitted from the inner bulb to pass through.By placing the shield body inside the outer bulb provided with a phosphor layer, the shield This design makes the body invisible in appearance, prevents the external dimensions from increasing, and provides a sufficient shielding effect.

(Example) As shown in the mi diagram, an induction coil 2 is installed around the outer circumference of the inner valve 1.
Further, an outer valve 3 is disposed outside the induction coil 2 to surround the inner valve 1. Inside the inner valve 1, several zzTorr of mercury vapor and several Torr of rare gas are sealed and sealed. The induction coil 2 is wound around the outer circumference of the inner valve 1 in the form of 1 to r & tan.
This induction coil 2 receives a signal of several tens of AHz or more from the power oscillator 4.
By applying a high frequency current, preferably 1 to 100 MHz, the gas atoms sealed in the inner bulb 1 are excited to emit ultraviolet rays by guided radiation.

However, inner bulb 1 is the main ultraviolet #! (Ultraviolet rays are most efficiently converted into visible light in the phosphor layer, which will be described later).In order to allow visible light to easily pass through, materials that are particularly transparent to main ultraviolet rays, such as iron-free lath or quartz glass, are used. There is. The outer bulb 3 is formed into a spherical shape using a positive electrode, and its inner peripheral surface is coated with a phosphor N5 to convert the ultraviolet rays emitted from the inner bulb 1 into white light. The phosphor layer 5 is formed of one type of phosphor or a mixture of multiple types of phosphors.

The power oscillator 4 is housed in a metal base 6 provided at the base of the outer bulb 3, and a mount 7 fixed to the base 6 fixes the inner bulb 1 in a fixed position. At the bottom of base 6 is a lamp socket! Ii compatible base 8
is formed. The cap 8 may be either a screw type or a swan type. By the way, induction coil 2 and outer valve 3
A shield body 9 made of a net-like material and through which the light rays emitted from the inner bulb 1 can pass is arranged between the induction coil 2 and the induction coil 2 . The shield body 9 is a mesh-like combination of conductive magnetic metal wires, and prevents the high-frequency electromagnetic field radiated from the induction coil 2 from leaking to the outside. The shield body 9 may be of a punched metal shape, but with a configuration of -1° or more, the ultraviolet rays emitted from the inner bulb 1 pass through the mesh of the shield body 9 and are coated on the inner circumferential surface of the outer bulb 3. The phosphor layer 5 converts the ultraviolet rays into white light, and at this time, part of the ultraviolet rays is interrupted by the shield 9 and forms a shadow, but the phosphor layer 5 diffuses the ultraviolet rays. Therefore, the lamp as a whole emits visible light with uniform brightness. In addition, a shield body 9 having a mesh is disposed inside the outer bulb 3, and is made of fluorescent material! Since it is blocked by gJ5 and cannot be seen from the outside, there is almost no difference in appearance compared to the case where the shield body 9 is not provided, resulting in an excellent appearance. Furthermore, since the shield body 9 is not disposed outside the outer bulb 3, the overall shape does not become large.

In the above example, the outer bulb 3 has a spherical shape, but it may also have a spheroidal shape, a cylindrical shape, etc. If necessary, the power oscillating section 4 may be placed separately and supplied with power using a coaxial cable or the like. You may also do so.

(Specific example) In order to confirm the effect, measurements were performed under the following setting conditions. As the inner bulb 1, a spherical body made of quartz plus with a diameter of about 30 inches is used, and the inside is filled with mercury vapor of several xzT.
orr, neon gas was sealed in ITorr. The induction coil 2 is located at about the lower third of the inner valve 1.
The turn was tightly wound into a headband shape. The power oscillator 4 was set to supply approximately 20 W of power to the induction coil 2. The shield body 9 is made by combining nickel wires of 0.5111 in a mesh shape, and the mesh pitch is 5zz.
I made it so that The outer envelope diameter of the shield body 9 is approximately 50i
+t. Furthermore, the outer bulb 3 is a spherical body with a diameter of about 70 yz, has a white phosphor 715 such as calcium halophosphate formed on the inner peripheral surface, and has nitrogen gas of about 1 atm between the outer bulb 3 and the inner bulb 1. was enclosed.

The power oscillator 4 is a modified Corbitz oscillator circuit powered by a DC power source obtained by rectifying and smoothing a 100V commercial power source, and is designed to obtain an oscillation output of approximately 10MHz, with an output stage directly connected to the induction coil 2. . This power oscillation section 4 is
It was housed in a metal base 6 formed into a cylindrical shape with a diameter of about 60i+z and a length of about 50zz.

With the above configuration, AClooV can receive 25
A power of about 17 W was supplied to the induction coil 2 in response to an input of W, and a luminous flux of about 6001 m of white light was obtained. Here, the electromagnetic radiation ranges from 1 to 10 at a distance of 31 from the lamp.
It was 40 dBμV/1 or less over the entire range of 0100O, which was at a practically harmless level for practical use.

[Effects of the Invention] As described above, the present invention includes an inner bulb filled with discharge gas, and an induction coil to which a high-frequency current output from a power oscillation section is applied to apply a high-frequency electromagnetic field to the discharge gas in the inner bulb. , a phosphor layer surrounding the inner bulb on the outside of the induction coil and the inner bulb, which has a phosphor layer on the periphery that converts the ultraviolet rays emitted when the discharge gas is inductively discharged by the electromagnetic field into visible light. An outer bulb is arranged to surround the induction coil outside the induction coil and inside the phosphor layer to block leakage of the electromagnetic field generated by the induction coil to the outside, and an inner valve It consists of a shield body made of a metal mesh that allows most of the ultraviolet rays emitted from the body to pass through.The shield body is placed inside the outer bulb on which the phosphor layer is formed, so the shield body is It has the advantage of being invisible from the outside because it is shielded by the phosphor layer, giving it an excellent appearance.Furthermore, although the shield body creates a shadow area for ultraviolet rays, it is diffused by the phosphor layer.
This has the advantage that uneven brightness does not occur outside the outer bulb. Further, since the shield body is disposed within the outer bulb, it is possible to prevent the external dimensions from increasing, and there is an advantage that a metal having a sufficient shielding effect can be used as the shield body. As a result of the above, it is possible to obtain a lamp that is small in size, has an excellent appearance, and is free from radio wave interference due to electromagnetic radiation.

[Brief explanation of the drawing]

FIG. 1 is a sectional view showing one embodiment of the present invention, FIG. 2 is a sectional view showing a conventional example, and FIG. 3 is a sectional view showing another conventional example. 1 is an inner bulb, 2 is an induction coil, 3 is an outer bulb, 4 is a power oscillation section, 5 is a phosphor layer, 8 is a base, and 9 is a shield body. Agent Patent Attorney Ishi 1) Chief 7 Figure 1 Figure 3 1... Inner bulb 2... Induction filter 3... Outer bulb 4... Power oscillation section 5... Phosphor layer 8...・Base 9...Shield body diagram 2

Claims (7)

[Claims] (1) An inner bulb filled with discharge gas, an induction coil that is energized with a high-frequency current output from the power oscillator and applies a high-frequency electromagnetic field to the discharge gas in the inner bulb, and an induction coil that applies a high-frequency electromagnetic field to the discharge gas in the inner bulb, and the electromagnetic field to induce the discharge gas. The outer bulb has a phosphor layer on its circumferential surface that converts ultraviolet rays emitted when it is discharged into visible light, and is disposed outside the inner bulb to surround the inner bulb, and the induction coil. It is arranged to surround the induction coil on the inside of the phosphor layer at the outside line, and blocks leakage of the electromagnetic field generated by the induction coil to the outside, and also allows most of the ultraviolet rays emitted from the inner bulb to pass through. An electrodeless discharge lamp characterized by comprising a shield body made of a metal mesh body. (2) Mercury and a rare gas of several Torr or less are sealed in the inner bulb, and the tube wall material of the inner bulb is made of a material that is transparent to ultraviolet rays emitted from the inner bulb. An electrodeless discharge lamp according to claim 1. (3) The electrodeless discharge lamp according to claim 1 or 2, characterized in that the power oscillation section is disposed integrally with the outer bulb. (4) The electrodeless discharge lamp according to claim 3, further comprising a base connectable to a lamp socket. (5) The electrodeless discharge lamp according to any one of claims 1 to 4, wherein the output frequency of the power oscillation section is set to 1 to 100 MHz. (6) The electrodeless discharge lamp according to any one of claims 1 to 5, wherein the outer bulb has any one of a spherical shape, a spheroidal shape, and a cylindrical shape. (7) The electrodeless discharge lamp according to any one of claims 1 to 6, wherein the phosphor layer converts ultraviolet light into white light.