JP2002164021A - Fluorescent lamp and luminaire - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a fluorescent lamp for improving mechanical strength of a terminal deriving part of external electrodes, and a luminaire using this fluorescent lamp. SOLUTION: This fluorescent lamp has a pair of electrodes comprising at least one external electrodes 4 arranged on an outside surface of a light transmissive airtight vessel 1 so as to cause discharge in the light transmissive airtight vessel 1 sealed with a discharge medium mainly composed of rare gas, and arranging a phosphor layer on the inside surface side, and external lead wires 5 having a base end part 5a embedded in an end part of the light transmissive airtight vessel 1 without being exposed inside the light transmissive airtight vessel 1, and having an intermediate part 5b folded back along the light transmissive airtight vessel 1, and having a tip part 5c connected to one end part of the external electrodes 4. The external lead wires 5 may be separately arrnged in one end part of the light transmissive airtight vessel 1, and may be dispersively arranged in both end parts.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a fluorescent lamp having an external electrode and a lighting device using the same.

[0002]

2. Description of the Related Art In general, a fluorescent lamp emits ultraviolet light by discharging mercury vapor or a rare gas sealed therein, and the generated ultraviolet light irradiates the fluorescent material layer, whereby the fluorescent light contained in the fluorescent material layer is emitted. The body excites and emits visible light. Then, the visible light emitted into the fluorescent lamp passes through the translucent airtight container and is led out to the outside, and can be used for illumination and the like.

By the way, since a fluorescent lamp using a rare gas discharge in which a rare gas such as xenon is sealed does not use mercury, which has a large environmental load, the influence on the environment at the time of disposal is small, and the temperature relative to the ambient temperature is low. There is an advantage that there is no dependence and the luminous flux rising characteristics are excellent.

As one mode of a fluorescent lamp utilizing a rare gas discharge, a pair of external electrodes having a band shape along the longitudinal direction are separated from and opposed to the outer surface of a thin and light-transmitting airtight container in which xenon is sealed. The one having the arranged structure is mainly used for reading. The external electrode is made of an aluminum foil adhered to a transparent synthetic resin sheet. The structure shown in FIGS. 11 and 12 is used to supply power to the external electrodes.

FIG. 11 is an enlarged plan view of a main part showing a connection portion between an external electrode and a terminal plate in a conventional fluorescent lamp.

FIG. 12 is a vertical sectional view of the same.

In each of the drawings, reference numeral 101 denotes a translucent airtight container,
102 is an external electrode and 103 is a terminal plate.

That is, in the vicinity of one end in the longitudinal direction of the light-transmitting airtight container 101, the tip of the terminal plate 103 is inserted between the external electrode 102 and the outer surface of the light-transmitting airtight container 101, and is connected to the external electrode 102. Connected. The terminal plate 103
It is formed by stamping a conductive metal plate such as a copper plate by press working, and its base end protrudes from the external electrode 102 to the outside. Then, a power supply harness wire is connected to the protruding portion of the terminal plate 103 by soldering. Therefore, power is supplied from the lighting circuit to the external electrodes via the power supply harness line and the terminal plate. The external electrode 102
The outside is covered with a transparent synthetic resin sheet (not shown) so that the external electrodes are insulated from each other and the connection between the external electrodes 103 and 102 is ensured.

[0009]

However, the use of the terminal plate increases the cost, and when the terminal plate is connected to the external electrode at one point or when the terminal plate is thin, the terminal plate is pulled or bent. When the stress on the terminal board is reduced,
When the tube diameter of the light-transmitting airtight container is reduced to, for example, 4 mm, the insulation at the connection portion of the external electrode is secured, the size of the terminal plate is restricted, and the mechanical strength and the adhesive strength of the terminal plate are reduced. And so on will be added as major issues.

Further, if the power is supplied from the same direction at one end of the fluorescent lamp, there is a problem that the connecting portion for the power supply expands and the fluorescent lamp cannot enter the device to be incorporated.

An object of the present invention is to provide a fluorescent lamp in which the mechanical strength of a terminal lead-out portion of an external electrode is improved, and a lighting device using the same.

Another object of the present invention is to provide a fluorescent lamp having the required mechanical strength of the terminal portion even if the light-transmitting airtight container has a small diameter, and an illumination device using the same.

It is still another object of the present invention to provide a fluorescent lamp having improved insulation between a terminal lead-out portion of an external electrode and the other external electrode, and a lighting device using the same.

Another object of the present invention is to provide a fluorescent lamp and a lighting device using the same, in which a connecting portion for supplying power to an external electrode does not cause a bulging which hinders incorporation into a device. The purpose of.

[0015]

A fluorescent lamp according to the present invention comprises an elongated light-transmitting airtight container; a discharge medium sealed in the light-transmitting airtight container and emitting ultraviolet light at the time of discharge; A phosphor layer disposed on the inner surface side of the container; and at least one of an external electrode disposed along a longitudinal direction of an outer surface of the translucent airtight container so as to generate a discharge in the translucent airtight container. A pair of electrodes; a base end portion is buried at an end of the light-transmitting airtight container without being exposed in the light-transmitting airtight container, an intermediate portion is folded back along the light-transmitting airtight container, and a front end portion And an external lead wire connected to one end of the external electrode.

In the present invention and each of the following inventions, definitions and technical meanings of terms are as follows unless otherwise specified.

<About the Translucent Airtight Container> The translucent airtight container is most preferably manufactured by sealing both ends of a glass bulb having both ends opened or sealing an open end of a glass bulb having one end opened. Although it is preferable because it is easy and the cost is low, it may be formed of a translucent ceramic if necessary.

As the glass, soft glass, semi-hard glass, hard glass, quartz glass or the like can be appropriately selected and used. The means for sealing the opening of the translucent airtight container is not limited to a specific structure, and various kinds of conventionally known sealing means can be appropriately employed. For example, by using a pinch seal or a bead glass sealing means, the sealing of the translucent airtight container and the embedding of a base end portion of an external lead wire described later can be performed together.
Further, the “light-transmitting” of the light-transmitting airtight container does not require that the entire light-transmitting airtight container is light-transmitting, and is radiated from the phosphor layer at least upon discharge. It is sufficient that a portion (for example, an aperture) from which visible light is to be extracted to the outside is transparent to the light. In addition, that the light-transmitting airtight container is elongated means that the light-transmitting airtight container has a length that is at least twice the outer diameter of the discharge container.

The translucent airtight container can be about 6 to 12 mm in the case of a fluorescent lamp for reading. For fluorescent lamps for LCD backlights,
It can be about 5 mm.

Further, the transparent airtight container may be either a straight tube or a curved tube. For example, U-shaped
Various shapes such as a U-shape, a double U-shape, an L-shape, a U-shape, an annular shape, and a semi-annular shape can be adopted.

Furthermore, in the present invention, the translucent airtight container may have a flat cross section, a square shape, a triangular shape, or the like.

<About Discharge Medium> The discharge medium may be any medium as long as at least one of them is a medium that emits ultraviolet rays by discharging between a pair of electrodes composed of external electrodes. When a rare gas is mainly used, xenon, neon, argon, krypton, helium, or the like can be used alone or in any combination. Further, in addition to the rare gas, for example, a rare gas halide such as KrF or ArCl or a simple halogen may be added. As the halogen, iodine, bromine, and chlorine can be used. If the element exists as a vapor in the range of several hundreds to about 1 MPa, discharge is possible.

<Regarding the Phosphor Layer> The phosphor layer is used to convert the wavelength of ultraviolet light emitted by the discharge medium due to discharge into visible light. And it is arrange | positioned at the inner surface side of a translucent airtight container. Further, the phosphor layer may be provided over the entire circumference on the inner surface side of the translucent airtight container, or may be provided so as to form an aperture extending in a slit shape along the longitudinal direction. . The “inner side of the translucent airtight container” refers to a mode in which the phosphor layer is formed directly on the inner surface of the translucent airtight container, and the inner surface of the translucent airtight container via a protective film or a reflective film. And indirectly forming a phosphor layer.

Next, a single phosphor or a mixture of plural phosphors can be used. It is possible to use a white-light-emitting three-wavelength light-emitting phosphor obtained by mixing red, green, and blue light-emitting phosphors. However, in the present invention, a fluorescent lamp of each emission color of R (red), G (green) or B (blue) may be used as the discharge lamp. If necessary, the use of one or more sets of fluorescent lamps of each emission color is permitted. In the case of such a configuration, a red-emitting phosphor is used for a discharge lamp of R (red) emission color, a green-emitting phosphor is used for a discharge lamp of each G (green) emission color, and B (blue). ) A blue light-emitting phosphor is used independently for a discharge lamp of a luminescent color.

The phosphor layer may have a single layer structure or a multilayer structure. In the latter case, the type of phosphor may be different for each layer. Further, a third layer made of another substance that is not a phosphor, for example, a conductive layer, a discharge state improving layer mainly composed of a metal oxide, or the like may be interposed between the phosphor layers. Furthermore, as described later, a reflection film can be provided between the phosphor layer and the inner surface of the light-transmitting airtight container facing the phosphor layer.

<Regarding paired electrodes> The paired electrodes are at least one pair or a plurality of pairs, and if one of the pair is an external electrode, the other may be either an internal electrode or an external electrode. . Further, in the case of a plurality of pairs of electrodes, it is allowed that some of the plurality of pairs of electrodes are shared with a different pair of electrodes.

The external electrode is disposed substantially in contact with the outer surface of the translucent airtight container. And, it is preferably made of a conductive thin film. As the conductive thin film, a conductive metal foil such as aluminum, silver, and copper, a conductive metal vapor-deposited film, a plated film, a conductive metal foil, and a conductive paste, which are adhered to a transparent resin sheet described later, are screened. Printed coating film, IT
An O film, a NESA film, or the like can be used. In addition,
Although the thickness of the conductive thin film is not limited, it is generally 10 to
In the range of about 200 μm, preferably in the range of about 30 to 100 μm, good results can be obtained in terms of the contact property with the outer surface of the light-transmitting airtight container, the electric resistance and the like. When the external electrode is made of a conductive thin film, the external electrode may be formed in a ribbon shape, or may be formed in a deformed shape such as a mesh shape or a wavy shape.

However, the external electrode is not limited to the conductive thin film, and is made of a conductive material such as a coil or a mesh structure if necessary, and is arranged almost in contact with the outer surface of the light-transmitting airtight container. It can be in the form provided. In addition, the phrase “the outer electrode is disposed substantially in contact with the outer surface of the light-transmitting airtight container” means that the entire outer electrode is directly on the outer surface of the light-transmitting airtight container or a dielectric material such as an adhesive. Although it is desirable to make indirect contact through a substance, this is not an essential requirement, and generally means that the external electrode only needs to be in contact with the outer surface of the translucent airtight container. Further, the external electrode may have a size such that at least a part thereof extends in the longitudinal direction, that is, the axial direction of the light-transmitting airtight container. Then, there is a problem in that the terminal board is cut undesirably in the outer peripheral direction of the translucent airtight container. Alternatively, they can be arranged within an angle range forming a part of the outer periphery. Furthermore, when the external electrode is formed of any one of a coil, a mesh structure, and a transparent conductive film, these structures transmit light through the external electrode or through a gap between the external electrodes, and light is emitted to the outside. Since it is led out, it can be arranged on the entire periphery of the translucent airtight container. On the other hand, when the external electrode is made of a metal foil, the metal foil is not substantially light-transmitting, so that the angle forming a part of the outer periphery of the light-transmitting airtight container so as not to cover the aperture. Be arranged within the range.

When the external electrode is constituted by a coil,
The pitch can be set as desired. Since the pitch of the coil of the external electrode affects the obtained brightness, the pitch of the coil can be appropriately adjusted to achieve a desired brightness distribution in the lamp axis direction. When the external electrode is formed of a mesh structure, a plain weave, twill weave, or knitted structure of a metal wire can be used.
However, a punched metal plate may be used if necessary. In the case of using a knitted knitted structure, a thick cylinder is manufactured in advance, a light-transmitting airtight container is inserted therein, and then both ends of the knitted knitted structure are pulled to reduce the diameter of the knitted knitted structure. It can be in close contact with the outer peripheral surface of the light-tight container. Further, when the external electrode is formed of a transparent conductive film, an ITO film, a NESA film, or the like can be used. Furthermore, when the external electrode is formed of a metal foil, the metal foil is previously adhered to one surface of a transparent resin sheet described later, and is adhered to the outer surface of the transparent airtight container with an adhesive applied to the transparent resin sheet. It can be arranged by doing. However, it is also possible to attach the metal foil directly to the outer surface of the translucent airtight container. Further, the width of the external electrode may change in the axial direction of the light-transmitting airtight container.

Next, in order to bring the external electrode into contact with the outer surface of the light-transmitting airtight container, an adhesive is previously applied to the contact surface of the external electrode, and the external electrode is adhered to the light-transmitting airtight container. be able to. However, an adhesive may be applied to a portion of the translucent airtight container where the external electrode is to be contacted, and the external electrode may be adhered from above. Furthermore, without using an adhesive or an adhesive, the external electrode may be simply brought into contact with the portion to be contacted, and the light-transmitting resin sheet to which the adhesive has been applied may be wound over the entire periphery of the light-transmitting airtight container. Good.

Further, the arrangement of the paired electrodes will be described. That is, the electrode arrangement can be arbitrarily selected from the various embodiments described below.

1. Internal / External Electrode Configuration The internal / external electrode configuration is an electrode configuration in which one or more internal electrodes and one or more external electrodes are paired. Also,
This arrangement is divided into a short internal electrode and a long internal electrode extending along the longitudinal direction of the translucent airtight container.
In order to seal the internal electrode at the end or intermediate portion of the light-transmitting airtight container, various known sealing means such as a flare seal, a bead seal, and a pinch seal can be appropriately selected and used.

(1) Electrode arrangement using short internal electrodes In this electrode arrangement, short electrodes similar to those used in a normal internal electrode type fluorescent lamp are used.

(1-1) An electrode arrangement in which a single internal electrode is arranged at one end of a light-transmitting airtight container, and a single external electrode is arranged on the outer surface of the light-transmitting airtight container. An electrode arrangement in which a pair of internal electrodes are arranged at both ends of the airtight container and a single external electrode is arranged on the outer surface of the translucent airtight container.In this electrode arrangement, both the pair of internal electrodes form one pole of the lighting circuit. And a configuration in which an external electrode is connected to the other pole of the lighting circuit, and a pair of lighting circuits are prepared and one pole of each lighting circuit is separately connected to the internal electrode, and the external electrode is connected to the other pole of the pair of lighting circuits. And the same potential.

(1-3) Electrode arrangement in which internal electrodes are arranged at both ends of the light-transmitting airtight container, and a pair of external electrodes are arranged on the outer surface of the light-transmitting airtight container. In this electrode arrangement, the internal electrode and the external electrode are arranged. Are opposed to each other on a one-to-one basis.

(1-4) Internal electrodes are arranged at both ends and the middle of the light-transmitting airtight container, respectively, and a single external electrode is commonly opposed. (1-5) Both ends and the middle of the light-transmitting airtight container An electrode arrangement in which an internal electrode is disposed on each of the electrodes and an external electrode facing the internal electrode is disposed on the outer surface of the light-transmitting discharge vessel. (2) An electrode arrangement using a long internal electrode. An internal electrode is used that extends over substantially the entire length of the container. A structure in which both ends of the internal electrode penetrate both ends of the translucent airtight container and are led out to the outside, and only one end of the internal electrode penetrates one end of the translucent airtight container and is led out to the outside. However, there is a structure in which the other end is located inside the vicinity of the other end of the translucent airtight container.

2 External electrode type arrangement In this arrangement, a pair of external electrodes are arranged on the outer surface of the translucent airtight container so as to be spaced apart and opposed. One or more pairs of external electrodes can be arranged along the longitudinal direction of the translucent airtight container. In the case of the aperture type, the external electrodes must be arranged so as not to substantially prevent the projection of light from the aperture.

As long as at least one of the pair of electrodes is arranged so as to generate a discharge through the discharge medium inside the light-transmitting airtight container, either of the inside and the outside of the light-transmitting airtight container is used. There may be.

<Regarding the External Lead Wire> The external lead wire is made of a conductive metal wire, the base end of which is buried in the end of the translucent airtight container, and the intermediate portion along the translucent airtight container. And the tip is connected to the end of the external electrode,
It constitutes the terminal part of the external electrode. That is, the base end of the external lead wire is firmly fixed to the translucent airtight container by being embedded in the end of the translucent airtight container. However, the base end of the external lead wire must be in such a manner that the base end is not exposed to the inside of the light-transmitting hermetic container, that is, to the discharge space.

The embedding of the base end of the external lead wire can be performed, for example, by pinching the base end of the external lead wire to the pinch seal portion when pinching the end of the translucent airtight container. . Alternatively, bead glass in which the base end of the external lead wire is buried in advance is prepared, and this bead glass is used to seal the open end of the translucent airtight container. The external lead wires may be provided at either one end or both ends of the translucent airtight container. In addition, in order to bury the base end of the external lead wire at the end of the light-transmitting airtight container, it is preferable to use a conductive metal having a thermal expansion coefficient close to that of the buried portion of the light-transmitting airtight container at least for the buried portion. . For example, if the buried portion of the translucent airtight container is soft glass, a Dumet wire can be used at the base end. On the other hand, if semi-hard glass or hard glass is used, Kovar or tungsten can be used at the base end. Further, the conductive metal wire forming the external lead wire may have a circular cross section or a flat shape.

Next, the middle part of the external lead wire is folded back along the light-transmitting airtight container. This folding may be performed at any stage before and after the base end is buried. That is, since the base end of the external introduction line extends in the direction in which the tube axis extends at the end of the translucent airtight container and is buried, the intermediate portion is turned back so that the front end is the end of the external electrode. Can be located. The folded portion is allowed to have an appropriate shape such as a square shape having two bent portions forming substantially right angles, a semicircle bent into a semicircle, and the like. Also,
The folded portion may be in contact with the outer surface of the translucent airtight container, or may be separated.

Further, the tip of the external lead wire is connected to the end of the external electrode. Note that “connection” in this case means an electrical connection. As a means for connection, for example, soldering, bonding using a conductive adhesive, contact, welding, or the like can be used. In the case of connection by abutment, the tip of the external lead wire is overlapped on the outer surface or the inner surface of the external electrode, and the outer periphery of the light-tight airtight container is transmitted between the two electrodes, for example, from above the tip of the external electrode and the external lead wire. An appropriate pressing force may be applied by, for example, coating with a heat-shrinkable tube.

<Other Configurations> About the translucent insulating coating In order to mechanically protect the external electrodes, and to further secure the connection between the external electrodes and the external lead wires, if necessary, to further improve the insulation properties of the discharge lamp, A translucent insulating coating can be provided outside the external electrode. The translucent insulating coating is preferably transparent. The light-transmitting insulating coating may be heat-shrinkable or may be applied by dipping for the workability of the arrangement. However, a translucent insulating sheet may be wound.

2. About a protective film etc. If necessary, a protective film or an electron emitting material film made of alumina fine particles or the like can be formed on the inner surface of the translucent airtight container. When forming a protective film, a protective film may be formed between the phosphor layer and the inner surface of the translucent airtight container, or a protective film may be formed on the inner surface of the phosphor layer on the discharge space side. Is also good.
In addition, it is possible to form an electron emitting material film, and in this case, it is effective to avoid or reduce the occurrence of dark characteristics of the fluorescent lamp.

3. Regarding Reflection Film A reflection film can be provided between the phosphor layer and the inner surface of the light-transmitting airtight container facing the phosphor layer. As the constituent material of the reflective film, for example, fine particles of TiO ₂ or Al ₂ O ₃ can be used. Adjust the dispersion of these materials and apply them to the inner surface of the translucent airtight container except for the aperture,
By baking, a reflective film can be formed.

Then, by forming the reflection film,
Visible light generated from the phosphor layer and transmitted directly through the light-transmitting airtight container to be emitted to the outside can be reflected and led out of the aperture. Thus, the brightness of the aperture can be further increased.

4. Lighting Circuit Since fluorescent lamps use dielectric barrier discharge, lighting circuits generally include a power supply that outputs a high-frequency AC voltage with a waveform such as a square wave or a sine wave, or a pulse voltage with a high repetition frequency. A configuration in which a voltage is directly applied between the opposed electrodes without using an external current limiting impedance can be used. The pulse voltage can be obtained by, for example, half-wave rectification of a high-frequency AC voltage having a rectangular wave or a sine wave. Further, the lighting circuit can be constituted by an inverter.

<Function of the Present Invention> In the present invention, when the fluorescent lamp is turned on by connecting the electrodes forming a pair of the fluorescent lamp to the lighting circuit, the discharge medium is discharged into the translucent airtight container to emit the ultraviolet light. Is emitted. For example, in the case of xenon discharge, xenon has an excitation wavelength of 147, which is a resonance line.
and 172 nm. The generated ultraviolet light is incident on the phosphor layer to excite the phosphor, and emits light having a longer wavelength than the excited ultraviolet light, for example, visible light, so that wavelength conversion is performed. Light emitted from the phosphor layer led out can be used for illumination.

Further, by supplying power to the external electrode through an external lead wire whose base end is buried at the end of the translucent airtight container, the tensile strength when the power supply harness wire is pulled is remarkably increased. improves.

Further, since the intermediate portion of the external lead wire is folded back along the light-transmitting airtight container, the connection of the distal end portion of the external lead wire to the end portion of the external electrode becomes easy. For this reason, it is not necessary to protrude the connection piece from the external electrode to the external lead wire for connection, and the connection structure is simplified, and the length of the fluorescent lamp in the tube axis direction can be reduced.

A fluorescent lamp according to a second aspect of the present invention comprises an elongated light-transmitting airtight container; a discharge medium sealed in the light-transmitting airtight container and emitting ultraviolet light at the time of discharge; A phosphor layer provided; and a pair of electrodes formed of external electrodes spaced apart along the longitudinal direction of the outer surface of the light-transmitting airtight container so as to generate a discharge in the light-transmitting airtight container;
A base end is not exposed in the translucent airtight container at one end of the translucent airtight container and is buried separately from each other, an intermediate portion is folded back in the opposite direction along the translucent airtight container, and a distal end is formed. And a pair of external lead wires connected to one end of the external electrode, respectively.

The present invention defines a configuration in which a pair of electrodes are both formed of external electrodes, and a pair of external lead wires are disposed on one end side of the light-transmitting airtight container.

In other words, the external electrode is allowed to have an irregular shape such as a band (ribbon) shape, a mesh shape, a wave shape, or a comb shape. Further, the interval between the pair of external electrodes may be a constant parallel distance, or may change regularly along the tube axis direction. Further, the pair of external electrodes is preferably formed of a conductive thin film such as a foil. However, if necessary, a mesh structure formed by knitting fine metal wires, a press-punched molded product of a metal plate, or the like may be used. Good.

The pair of external lead wires is disposed at one end of the light-transmitting airtight container so as to be spaced apart from each other. The base end of the external lead wire can be embedded in the pinch seal when the light-tight container is pinch-sealed. However, by preparing a bead glass in which the base ends of the pair of external lead wires are separated in advance and sealing the glass tube using this bead glass, the light-transmitting airtight container is sealed at the same time. External leads can also be placed in place.

Thus, in the present invention, a pair of external lead wires are concentrated on one end side of the translucent airtight container, so that the wiring routing is simplified.

If necessary, the end of the light-transmitting airtight container on which the external lead wire is provided can be cantilevered.

Further, an intermediate portion between the pair of external lead wires is
Since they are folded in opposite directions, the distance required for insulation can be easily secured.

A fluorescent lamp according to a third aspect of the present invention comprises an elongated light-transmitting airtight container; a discharge medium sealed in the light-transmitting airtight container and emitting ultraviolet light at the time of discharge; A phosphor layer provided; and a pair of electrodes formed of external electrodes spaced apart along the longitudinal direction of the outer surface of the light-transmitting airtight container so as to generate a discharge in the light-transmitting airtight container; The base end is buried at both ends of the light-transmitting airtight container without being exposed in the light-transmitting airtight container, the intermediate portion is folded back along the light-transmitting airtight container, and the distal end is each one end of the external electrode. And a pair of external lead wires connected to the

The present invention defines a structure in which a pair of electrodes are both formed of external electrodes, and a pair of external lead wires are disposed at both ends of the translucent airtight container. That is, one external lead wire is provided at each end of the translucent airtight container.

Thus, in the present invention, the pair of external lead wires is distributed to both ends of the light-transmitting airtight container, so that the dielectric strength of the power supply portion is improved. In particular, when the diameter of the light-transmitting airtight container is small, the dielectric strength of the power supply portion is likely to be insufficient. Therefore, the present invention is suitable for a fluorescent lamp having an outer diameter of the light-transmitting airtight container of 6 mm or less.

Further, by disposing a pair of external lead wires at both ends of the translucent airtight container, the power supply harness lines can be distributed to the left and right, so that the floating between the power supply harness lines can be prevented. Since the capacitance is significantly reduced, the leakage current is reduced and the electrical characteristics are stabilized.

Further, the swelling of the power supply portion is smaller than that in the case where it is concentrated at one end. For this reason, the incorporation into the device becomes easy.

The fluorescent lamp according to the fourth aspect of the present invention is the third aspect of the present invention.
In the fluorescent lamp described above, the pair of electrodes formed of the external electrodes is such that the other end of the other external electrode facing one end of the external electrode connected to the external lead wire is receded to the one end side. It is characterized by.

The present invention defines a configuration in which the end portions of the pair of external electrodes are asymmetric so as to be separated from the external lead wires. That is, when the pair of external electrodes is symmetrically arranged with respect to the tube axis, both ends along the tube axis direction of the pair of external electrodes face each other. On the other hand, in the present invention, the other end of the other external electrode facing one end of the external electrode connected to the external lead wire is receded to the one end side. That is, the pair of external electrodes are arranged asymmetrically with respect to the tube axis.

Thus, according to the present invention, since the distance between the external lead wire and the other external electrode facing the external lead wire becomes large, even if the power supply harness wire is led to the other external electrode side. Thus, a required insulation distance can be obtained.

The fluorescent lamp according to the fifth aspect of the present invention is the first aspect of the present invention.
5. The fluorescent lamp according to any one of Items 4 to 4, further comprising a power supply harness wire having a distal end connected to a base end portion of the external lead wire.

The present invention defines a configuration for connecting the power supply harness wire to the external lead wire. That is, since the base end of the external lead wire is buried and fixed in the end of the translucent airtight container, the base end portion has a higher tensile strength than the tip end portion. In addition, the distal end portion of the external lead wire is relatively mechanically weak because the distal end is connected to the external electrode. Therefore, by connecting the power supply harness wire to a portion closer to the base end than the middle folded portion of the external lead wire, the stress acting on the external electrode when the power supply harness wire is pulled is reduced.

Thus, in the present invention, by connecting the power supply harness wire to the base end portion of the external lead wire, the tensile strength is further improved.

The fluorescent lamp according to the sixth aspect of the present invention provides the fluorescent lamp according to the fifth aspect.
The above-described fluorescent lamp is characterized in that it comprises an insulating holder attached to the end of the translucent airtight container so as to surround the distal ends of the external lead wire and the power supply harness wire.

The present invention defines a configuration having an insulating holder. The insulating holder is preferably formed by molding, for example, an insulating material such as rubber having appropriate elasticity. Further, the insulating holder may be provided with a cap portion fitted to the end of the light-transmitting airtight container and a pipe-shaped portion from which the power supply harness wire is led out, and adopt, for example, a substantially L-shaped structure. it can. In the case of a configuration in which the external lead wire is provided only at one end of the translucent airtight container, the insulating holder may be provided only at the one end or may be provided at both ends. . In the latter case, the fluorescent lamp can be supported at both ends. When the external lead wires are provided at both ends of the translucent airtight container, insulating holders are provided at both ends.

Thus, in the present invention, since the distal end portions of the external lead wire and the power supply harness wire are surrounded by the insulating holder, the external lead wire is folded by protecting these members. Therefore, it is possible to prevent the folded portion from being deformed by being pushed by the external force, thereby preventing the connection portion of the external electrode from being damaged.

Further, a fluorescent lamp can be supported by using an insulating holder.

The fluorescent lamp according to the seventh aspect of the present invention is the first aspect of the present invention.
7. The fluorescent lamp according to any one of items 6 to 6, further comprising a light-transmitting insulating coating disposed on the outer periphery of the light-transmitting airtight container from above the connection portion between the external lead wire and the external electrode. I have.

In the present invention, the light-transmitting insulating coating can be formed, for example, by a light-transmitting heat-shrinkable tube or dipping. In the case of a light-transmitting insulating coating formed by a light-transmitting heat-shrinkable tube, the connection between them can be formed as required by simply pressing the tip of the external lead wire and the external electrode. However, needless to say, in order to ensure higher connection reliability, connection using a conductive adhesive or the like can be used together. Further, even when the connection between the external lead wire and the external electrode is performed by soldering, since the light-transmitting insulating coating is provided, the two are pressed against each other, so that the reliability of the connection is improved.

Thus, according to the present invention, the provision of the translucent insulating coating can improve the dielectric strength of the fluorescent lamp.

Further, the connection between the external lead wire and the external electrode is improved, and the reliability is improved.

An illuminating device according to an eighth aspect of the present invention provides an illuminating device main body; a fluorescent lamp according to any one of the first to seventh aspects disposed on the illuminating device main body; and a lighting circuit for energizing the fluorescent lamp. ; Characterized by having;

In the present invention, the term “illumination device” is a broad concept including all devices utilizing the light emission of a fluorescent lamp. For example, a reading device and a scanner, a copier, a facsimile or a multifunction machine having the same are provided. And a backlight unit and a liquid crystal display device including the same, and a device incorporating the liquid crystal display device. Devices incorporating a liquid crystal display device include, for example, devices incorporating a liquid crystal display device such as personal computers, navigation devices, personal digital assistants, and liquid crystal television receivers,
And instrument panel lighting devices for vehicles such as automobiles, decorative lighting fixtures, indicator lights, and sign lights.

The “illumination device main body” refers to the remaining portion of the illumination device excluding the discharge lamp and the lighting circuit.

[0080]

Embodiments of the present invention will be described below with reference to the drawings.

FIG. 1 is a process diagram showing a manufacturing process after the external electrodes are provided in the first embodiment of the fluorescent lamp of the present invention.

FIG. 2 is an enlarged cross-sectional view of the same.

The fluorescent lamp of the present embodiment shown in each figure has a light-transmitting airtight container 1, a phosphor layer 2, an aperture 3, a pair of external electrodes 4, 4, a pair of external lead wires 5, 5, a light-transmitting lamp. A heat shrink tube 6 and a power supply harness wire 7 are provided.

<Translucent Hermetic Container 1> The translucent hermetic container 1 is made of lead glass, has an outer diameter of 8 mm, and is formed by pinching and sealing the open end of an elongated glass tube 1a having an open end. And a pinch seal portion 1b and an exhaust tip off portion 1c. And the translucent airtight container 1
Is filled with a rare gas containing xenon as a main component at a pressure of 93 kPa as a discharge medium after exhaust.

<Regarding Phosphor Layer 2>
A wavelength-emitting phosphor is used as a main component, and is attached to the inner surface of the translucent airtight container 1 except for an aperture 3 described later. The phosphor layer 2 is formed by applying a phosphor dispersion liquid flowing down into the glass tube 1a at the stage of the glass tube 1a, followed by baking.

<Regarding Aperture 3> Aperture 3
Is formed at a portion where the phosphor layer 2 is not formed in the translucent airtight container 1 as described above. Therefore, the portion of the aperture 3 of the light-transmitting airtight container 1 is seen through the light-transmitting airtight container 1 through the glass bulb 1a.

<Regarding the pair of electrodes 4, 4> The pair of external electrodes 4, 4 are each made of aluminum foil, and are adhered to the outer surface of the light-transmitting airtight container 1 in parallel at the position where the aperture 3 is sandwiched therebetween. It is arranged by wearing. The external electrodes 4 extend over most of the translucent airtight container 1 in the tube axis direction.

<Regarding a Pair of External Lead Wires 5 and 5> A pair of external lead wires 5 and 5 have a diameter of 0.4 mm and a length of 30 mm.
2mm of the base end 5a
m is separately embedded in the pinch seal portion 1b of the translucent airtight container 1. Further, the intermediate portion 5b is folded back along the translucent airtight container 1 in the opposite direction to each other to form a distal end portion 5c.
Extend over the external electrodes 4, 4. Further, the tip 5c
Are connected to one ends of the external electrodes 4 and 4 by soldering. Reference numeral 8 denotes an aluminum solder, which connects between the distal ends of the external lead wires 5 and 5 and the external electrodes 4 and 4.

<Regarding Translucent Heat-Shrinkable Tube 6> The translucent heat-shrinkable tube 6 is made of a heat-shrinkable transparent fluororesin, and is transparent from above the external electrodes 4 and 4 and the tips of the external lead wires 5 and 5. The outer periphery of the light-tight container 1 is covered.

<Regarding Power Supply Harness Wire 7> The power supply harness wire 7 is connected to the base end portions of the external lead wires 5 and 5 by solder 9.

<About the manufacturing process of the fluorescent lamp> The connection of the external electrodes 4 and 4 and the external lead wires 5 and 5 of the fluorescent lamp, the coating of the translucent heat-shrinkable tube 6 and the power supply harness wire 7
The manufacturing process for the connection is as shown in FIG. That is, as shown in FIG. 1A, a pair of external lead wires 5, 5, 5
After burying its base end and attaching it, a pair of external electrodes 4 and 4 are attached and arranged as shown in FIG.
The external lead wires 5 and 5 are folded back in the opposite directions along the translucent airtight container 1 as shown in FIG. 4A, and the translucent heat-shrinkable tube 6 is placed on the translucent airtight container 1 as shown in FIG. The outer periphery of the light-transmissive heat-shrinkable tube 6 is covered by applying heat and shrinking by blowing hot air. Finally, the power supply harness wire 7 is soldered to the external lead wires 5 and 5 as shown in FIG.

FIG. 3 is a partially cutaway plan view showing a second embodiment of the fluorescent lamp of the present invention.

FIG. 4 is an enlarged side sectional view of the same.

FIG. 5 is a front view showing the bead glass.

In each figure, the same parts as those in FIG. 1 are denoted by the same reference numerals, and description thereof will be omitted. In the present embodiment, the arrangement of the translucent airtight container 1 ′, the external electrodes 4, and the arrangement of the external leads 5 are different.

That is, the translucent airtight container 1 'is made of semi-hard glass, has an outer diameter of 4 mm, and has a pair of bead glasses 1 at both open ends of an elongated glass tube 1a' open at both ends.
d and 1d are sealed by glass welding. Each of the pair of bead glasses 1d, 1d includes a glass bead 1b1 and an external lead wire 5.

The external electrode 4 is previously adhered to the translucent resin sheet 6 ′, and an adhesive is applied to the surface of the translucent resin sheet 6 ′ to which the external electrode 4 is adhered, so that the translucent resin sheet 6 ′ is attached. The outer surface of the light-transmitting airtight container 1 is wound around the outer surface of the light-transmitting airtight container 1 in a so-called seaweed winding shape so that the outer surface of the light-transmitting airtight container 1 is disposed. Thus, the translucent resin sheet 6 'and the transparent heat-shrinkable tube 6 constitute a translucent insulating coating.

The external lead wire 5 has a proximal end 5a made of a Kovar wire having a diameter of 0.6 mm and a length of 3 mm, and about 1.5 mm of the Kovar wire is embedded in the glass bead 1d1. The intermediate portion 5b and the tip 5c have a diameter of 0.4 mm.
It is made of a dumet wire having a length of 20 mm and a length of 20 mm. And
The external lead wires 5, 5 are disposed at both ends of the translucent airtight container 1, and the intermediate portion 5b is folded back in a U-shape.

FIG. 6 is a partially cutaway front view showing the inside of an insulating holder in a third embodiment of the fluorescent lamp of the present invention.

FIG. 7 is a partially cutaway side view.

In each figure, the same parts as those in FIGS. 3 to 5 are denoted by the same reference numerals, and description thereof will be omitted. This embodiment is different in that a pair of insulating holders 10 and 10 are provided.

That is, the pair of insulating holders 10, 10
Is made of a rubber molded article, is disposed at both ends of the translucent airtight container 1, and is integrally provided with a cap-like portion 10a and a pipe-like portion 10b. Cap-shaped part 10a
Is attached to the end of the translucent airtight container 1 so that the insulating holder 10 is mounted and surrounds at least a part of the external lead wire 5 and the connection portion between the external electrode 4 and the external lead wire 5. ing. The pipe-shaped portion 10b projects laterally from the tip of the cap-shaped portion 10a, and a power supply harness wire is inserted therein.

FIG. 8 is a partially cutaway plan view showing a fourth embodiment of the fluorescent lamp of the present invention.

In the figure, the same parts as those in FIGS. 3 to 5 are denoted by the same reference numerals, and description thereof will be omitted. The present embodiment is different in that the power supply harness wire 7 is connected to the base end portion of the external lead wire 5 and the pair of external electrodes 4 and 4 are arranged asymmetrically with respect to the tube axis. .

That is, the power supply harness wire 7 is soldered to a portion closer to the base end portion 5a than the folded portion formed at the intermediate portion 5b of the external lead wire 5.

In the pair of external electrodes 4, the edge of the other end of the other external electrode 4 that faces one end to which the external lead wire 5 is connected is receded to the one end.

FIG. 9 is a partially cutaway plan view showing a fifth embodiment of the fluorescent lamp of the present invention.

In the figure, the same portions as those in FIGS. 3 to 5 are denoted by the same reference numerals, and description thereof will be omitted. In the present embodiment, the external lead wire 5 'is different.

That is, the external lead wire 5 ′ is composed of the first portion 5 A in which the base end 5 a is buried at the end of the translucent airtight container 1, and the second lead 5 5B. The first portion 5A extends along the tube axis direction. The second part 5B is connected by forming the twisted part 5d together with the first part 5A after attaching the external electrode 4 to the translucent airtight container 1 and disposing the same. In this embodiment, the base portion of the first portion 5A connects the portion 5a, the portion of the second portion 5B folded along the translucent airtight container 1 connects the intermediate portion 5b, and the external electrode 4. The respective portions constitute the distal end portion 5c.

FIG. 10 is a conceptual cross-sectional view showing an image reading device as one embodiment of the illumination device of the present invention.

In the figure, reference numeral 11 denotes an image reading optical system;
Is a signal processing device, 13 is a document placing surface, 14 is a lighting circuit,
15 is a case.

In the present embodiment, the image reading optical system 11 includes a fluorescent lamp 11a, a mirror 11b, and an integrated lens 11.
c and the charge-coupled device 11d are main components. Although not shown, a fluorescent lamp, a cellphonic lens, and a charge-coupled device may be main components. The fluorescent lamp 11a has the structure shown in FIGS. Then, the light emitted from the aperture is radiated through the document placing surface 13 toward a document (not shown). The light reflected from the document is reflected by a mirror 11b in a predetermined direction, condensed by an integrated lens 11c, and received by a charge-coupled device 11d, that is, a CCD.

The signal processing device 12 processes the output signal of the light receiving means 11b to form an image signal.

The lighting circuit 14 lights the fluorescent lamp 11a at a high frequency.

[0115] The case 15 houses the above components inside.

Then, the image reading optical system 11 and the original placing surface 13 are relatively scanned. That is, in the process in which one or both are driven and moved by the driving mechanism (not shown) in the opposite direction, the charge-coupled device 11d sequentially receives reflected light from the document surface in a direction perpendicular to the moving direction. go. The image reading apparatus according to the present embodiment is applicable to OA equipment such as a copying machine, an image scanner, and a facsimile.

[0117]

According to the first aspect of the present invention, at least a discharge medium is sealed so as to generate a discharge in a light-transmitting hermetic container in which a discharge medium mainly composed of a rare gas is sealed and a phosphor layer is disposed on an inner surface side. One is a pair of electrodes consisting of external electrodes arranged along the longitudinal direction on the outer surface of the translucent airtight container, and the base end is exposed inside the translucent airtight container at the end of the translucent airtight container. The external electrode is connected to one end of the external electrode by being buried, the intermediate portion being folded back along the translucent airtight container, and the distal end being connected to one end of the external electrode. A fluorescent lamp with improved intensity can be provided.

According to the second aspect of the present invention, at least one of the discharge media is sealed in a light-transmitting airtight container in which a discharge medium mainly composed of a rare gas is sealed and a phosphor layer is disposed on the inner surface side. A pair of electrodes consisting of external electrodes disposed along the longitudinal direction on the outer surface of the light-transmitting airtight container, and a base end embedded in one end of the light-transmitting airtight container without being exposed to the inside of the light-transmitting airtight container. The intermediate portion is folded back along the translucent airtight container, and the end portion is provided with a pair of external leads connected to one end of the external electrode. Lamps can be provided.

According to the third aspect of the present invention, at least one of the discharge media is sealed so as to generate a discharge in a light-transmitting hermetic container in which a discharge medium mainly composed of a rare gas is sealed and a phosphor layer is disposed on the inner surface side. A pair of electrodes composed of external electrodes disposed along the longitudinal direction on the outer surface of the light-transmitting airtight container, and the base ends are embedded at both ends of the light-transmitting airtight container without being exposed inside the light-transmitting airtight container. The intermediate portion is folded back along the translucent airtight container, and the distal end portion is provided with a pair of external lead wires connected to one end portion of the external electrode. It is possible to provide a fluorescent lamp which can be easily incorporated into a device because the size of the power supply unit is small and the outside diameter is small.

According to the fourth aspect of the present invention, in addition, since the other end of the other external electrode facing the connection portion of the external lead wire of the one external electrode is retreated to one end, required insulation can be obtained. It is possible to provide a fluorescent lamp capable of obtaining a distance.

According to the fifth aspect of the present invention, a fluorescent lamp with further improved tensile strength can be provided by connecting the power supply harness wire to the base end portion of the external lead wire.

According to the sixth aspect of the present invention, in addition, the insulating holder is attached to the end of the light-transmitting hermetic container so as to surround the distal ends of the external lead wire and the power supply harness wire.
It is possible to provide a fluorescent lamp in which a connection portion of an external electrode is prevented from being damaged.

According to the seventh aspect of the present invention, in addition to the provision of the light-transmitting insulating coating on the outer periphery of the light-transmitting airtight container from above the connection between the external lead wire and the external electrode, the dielectric strength is improved. Fluorescent lamp can be provided.

According to an eighth aspect of the present invention, there is provided the fluorescent lamp according to any one of the first to seventh aspects, wherein the fluorescent lamp is provided in a lighting apparatus main body, and a lighting circuit for energizing the fluorescent lamp. Accordingly, it is possible to provide a lighting device having the effects of claims 1 to 8.

[Brief description of the drawings]

FIG. 1 is a process diagram showing a manufacturing process after an external electrode is provided in a first embodiment of a fluorescent lamp of the present invention.

FIG. 2 is an enlarged cross-sectional view of the same.

FIG. 3 is a partially cutaway plan view showing a second embodiment of the fluorescent lamp of the present invention.

FIG. 4 is an enlarged side sectional view of the same.

FIG. 5 is a front view showing the bead glass.

FIG. 6 is a partially cutaway front view showing the inside of an insulating holder in a third embodiment of the fluorescent lamp of the present invention.

FIG. 7 is a partially cutaway side view.

FIG. 8 is a partially cutaway plan view showing a fourth embodiment of the fluorescent lamp of the present invention.

FIG. 9 is a partially cutaway plan view showing a fifth embodiment of the fluorescent lamp of the present invention.

FIG. 10 is a conceptual cross-sectional view showing an image reading device as one embodiment of the illumination device of the present invention.

FIG. 11 is an enlarged plan view of a main part showing a connection portion between an external electrode and a terminal plate in a conventional fluorescent lamp.

FIG. 12 is a longitudinal sectional view of the same.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 1 ... Translucent airtight container 1a ... Glass bulb 1d ... Bead glass 3 ... Aperture 4 ... External electrode 5 ... External lead wire 5a ... Base end 5b ... Intermediate part 5c ... Tip 6 ... Translucent insulating tube 7 ... Power supply Harness wire 8… Aluminum solder 9… Solder

 ────────────────────────────────────────────────── ─── Continued on the front page (72) Inventor Ryuji Tsuchiya F-term (reference) 5C035 HH05 5C235 HH05 within 1 Harison Toshiba Lighting Co., Ltd., 5-2-2 Asahicho, Imabari City, Ehime Prefecture

Claims (8)

[Claims] An elongated light-transmitting airtight container; a discharge medium sealed in the light-transmitting airtight container and emitting ultraviolet light at the time of discharge; a phosphor layer disposed on an inner surface side of the light-transmitting airtight container; A pair of electrodes comprising at least one external electrode disposed along the longitudinal direction of the outer surface of the light-transmitting airtight container so as to generate a discharge in the light-transmitting airtight container; An external lead wire buried at the end of the hermetic container without being exposed in the translucent airtight container, an intermediate portion folded back along the translucent airtight container, and a distal end connected to one end of the external electrode; A fluorescent lamp comprising: 2. An elongated translucent airtight container; a discharge medium sealed in the translucent airtight container and radiating ultraviolet rays at the time of discharge; and a phosphor layer disposed on an inner surface side of the translucent airtight container; A pair of external electrodes spaced apart from each other along the longitudinal direction of the outer surface of the light-transmitting airtight container so as to generate a discharge in the light-transmitting airtight container; One end of the container is not exposed in the translucent airtight container and is buried apart from each other, the intermediate portion is folded back in the opposite direction along the translucent airtight container, and the end portions are each one end of the external electrode. And a pair of external lead wires connected to the fluorescent lamp. 3. An elongated light-transmitting airtight container; a discharge medium sealed in the light-transmitting airtight container and emitting ultraviolet light at the time of discharge; and a phosphor layer disposed on an inner surface side of the light-transmitting airtight container. A pair of external electrodes spaced apart from each other along the longitudinal direction of the outer surface of the light-transmitting airtight container so as to generate a discharge in the light-transmitting airtight container; A pair of external lead wires buried at both ends of the container without being exposed in the light-transmitting airtight container, the intermediate portion is folded back along the light-transmitting airtight container, and the tips are respectively connected to one end of the external electrode. And a fluorescent lamp comprising: 4. A pair of electrodes comprising an external electrode, wherein the other end of the other external electrode facing one end of the external electrode connected to the external lead wire is receded to one end. The fluorescent lamp according to claim 3, wherein: 5. The fluorescent lamp according to claim 1, further comprising a power supply harness wire having a distal end connected to a base end portion of the external lead wire. 6. The apparatus according to claim 5, further comprising an insulating holder attached to an end of the light-transmitting hermetic container so as to surround a distal end of the external lead wire and the power supply harness wire. Fluorescent lamp. 7. A light-transmitting insulating coating disposed on the outer periphery of a light-transmitting airtight container from above a connection between an external lead wire and an external electrode. The fluorescent lamp according to any one of the above. 8. A lighting device main body; and the fluorescent lamp according to claim 1 disposed on the lighting device main body;
A lighting circuit for energizing a fluorescent lamp;