Technical Field
[0001] The present invention relates to a high-pressure discharge lamp that has a discharge
vessel made of light-transmitting ceramic, and a lighting apparatus that uses the
lamp.
Background Art
[0002] There is a demand for a high-pressure discharge lamp having a smaller lamp power
of 20W or less, which is made of light-transmitting ceramic and which has a long lifetime
and a high efficiency.
[0003] It was found that a leak occurs at the seal shortly after the lamp is turned on even
if a small high-pressure discharge lamp is manufactured by proportionally reducing
directly the specifications of the discharge vessel and electrodes of a conventional,
relatively large, high-pressure lamp to meet the demand. This is because the modes
of conveying heat to the seal from a heat source such as discharge plasma, i.e., heat
conduction, convection and radiation, are unbalanced.
[0004] To realize small high-pressure discharge lamps, the prior art technology of high-pressure
discharge lamps should therefore be reviewed fundamentally to create new specifications
that are suitable for small, high-pressure discharge lamps.
[0005] In contrast, the present inventors have already invented a high-pressure discharge
lamp comprising light-transmitting ceramic that has a desirable long lifetime and
a preferable light-emission efficiency even with a small size. That invention has
already been filed as Japanese Patent Application No. 10-196322. The invention according
to this application discloses a light-transmitting ceramic discharge vessel comprising
a bulging section having both ends narrowed by continuous curved surfaces, and small-diameter
cylindrical sections communicating with the ends of the bulging section and having
an inner diameter smaller than the bulging section. It is very advantageous for a
small high-pressure discharge lamp to use this discharge vessel because the discharge
vessel can be formed integral with ease and has no optically and thermally discontinuous
portion.
[0006] It was found, however, a problem occurs depending on the size of the space in the
bulging section around the electrodes in the light-transmitting ceramic discharge
vessel having the shaped as described above. That is, when a high-pressure discharge
lamp which has been lightened is turned off, vapor of fillings such as a halide and
mercury which has been dispersed in the discharging space moves toward narrow gaps
in the small-diameter cylindrical sections of the light-transmitting ceramic discharge
vessel having a low temperature. At this time, a turbulent flow is generated around
the electrodes. If a turbulent flow is generated, the fillings such as halide and
mercury easily adhere to surfaces of distal ends of the electrodes. Once the fillings
have adhered to the distal ends of the electrodes, the electric discharging power
attenuates so operation errors are caused at starting or transition from a glow discharge
to an arc discharge becomes difficult. As a result, sputtering is excited and blackening
occurs in the light-transmitting ceramic discharge vessel due to the sputtering.
Disclosure of Invention
[0007] The first object of the present invention is to provide a small, high-pressure discharge
lamp which starts steadily.
[0008] The second object of the present invention is to provide a small, high-pressure discharge
lamp which easily transits from glow discharge to arc discharge.
[0009] The third object of the present invention is to provide a small, high-pressure discharge
lamp in which the light-transmitting ceramic discharge vessel is prevented from blackening
due to sputtering.
[0010] The forth object of the present invention is to provide a lighting apparatus using
the above described small, high-pressure discharge lamp.
[0011] The first high-pressure discharge lamp according to this invention is characterized
by comprising: a light-transmitting ceramic discharge vessel having an internal volume
of 0.1 cc or less and including a bulging section and small-diameter cylindrical sections
communicating with both ends of the bulging section, the bulging section having both
ends narrowed by a continuous curved surface, and the small-diameter cylindrical sections
having an inner diameter smaller than the bulging section; power-supplying conductors
each including a seal part and a halide-resistant section having a proximal end connected
to a distal end of the seal part and inserted respectively in the small-diameter cylindrical
sections of the light-transmitting ceramic discharge vessel, each of the halide-resistant
sections forming a slight gap to the inner surface of the small-diameter cylindrical
section; a pair of electrodes respectively arranged at the distal ends of one halide-resistant
parts and located in the bulging section of the light-transmitting ceramic discharge
vessel, with a distance d1 of 1.0 mm or above maintained between each of distal ends
of the electrodes and the inner surface of the light-transmitting ceramic discharge
vessel on a plane perpendicular to an axis of the light-transmitting ceramic discharge
vessel including the distal ends of the electrodes; seals made of ceramic-sealing
compound respectively making sealing between the small-diameter cylindrical sections
of the light-transmitting ceramic discharge vessel and the seal parts of the power-supplying
conductors; and a discharge medium containing metallic halide and filled in the light-transmitting
ceramic discharge vessel.
[0012] In the present invention and each invention described below, the terms are defined
to have the following technical meanings, unless otherwise specified:
(Light-transmitting Ceramic Discharge Vessel)
[0013] "Light-transmitting ceramic discharge vessel" means a discharge vessel made of light-transmitting
and heat-resistant materials. Among these materials are: a single-crystal metallic
oxide such as sapphire; a polycrystalline metallic oxide such as translucent, airtight
aluminum oxide, yttrium-aluminum garnet (YAG) or yttrium oxide; and a polycrystalline
non-oxide such as aluminum nitride (AIN). The term "light-transmitting" is used in
the sense that the light generated by discharge may be guided to the outside, passing
through the discharge vessel. It may mean either transparency or light-diffusing property.
[0014] To manufacture the light-transmitting ceramic discharge vessel, the bulging section,
or center section, and the small-diameter cylindrical sections connected to the ends
of the bulging section is preferably formed integral first. Otherwise, the light-transmitting
ceramic discharge vessel can be also formed in a manner that the bulging section is
molded preliminarily with the both ends narrowed by a continuous curved surface integrally,
and then a pair of small-diameter cylindrical sections preliminarily molded are fitted
in the distal ends of the bulging section respectively and sintered.
[0015] The internal volume of the light-transmitting ceramic discharge vessel is defined
to 0.1 cc or less because the present invention relates to the small, high-pressure
discharge vessel.
[0016] The internal volume of the light-transmitting ceramic discharge vessel is measured
in the following manner: the discharge vessel is put in water to fill the inside with
water; opening ends of the small-diameter cylindrical section provided at the both
ends of the discharge vessel are closed; the discharge vessel is taken out of water;
and then water contained in the discharge vessel is measured.
(Power-Supplying Conductors)
[0017] The Power-Supplying conductor is provided to at least one of the small-diameter cylindrical
section of the light-transmitting ceramic discharge vessel.
[0018] "Power-Supplying conductors" serve to supply power from a power supply through a
ballast means, thus applying a voltage between the electrodes to start the high-pressure
discharge lamp, and supplying a current to light the high-pressure discharge lamp.
They are sealed airtightly to the small-diameter cylindrical sections by the means
that will be described later.
[0019] The power-supplying conductors each have a seal part and a halide-resistant part.
[0020] "Seal part" is made of such material that the junction between it and the small-diameter
cylindrical section may be sealed by the seal made of ceramic-sealing compound, which
will be described later. "Seal part" is sealed to the junction between the small-diameter
cylindrical section and the seal part of the power-supplying conductor through a ceramic
tube. The seal part of the power-supplying conductor can be made of niobium, tantalum,
titanium, zirconium, hafnium, or vanadium. As a characteristic of the seal part, it
does not matter whether the seal part allows passage of hydrogen and oxygen or not.
These materials, however, exhibit permeability to hydrogen and oxygen. If aluminum
oxide is used, it is desirable that the seal part be made of niobium or tantalum,
because niobium and tantalum have average thermal expansion coefficients, which are
almost equal to those of aluminum oxide. Niobium and tantalum have average thermal
expansion coefficients, which differ only a little from those of yttrium oxide and
YAG. If aluminum nitride is used as the material of the light-transmitting ceramic
discharge vessel, the seal part should better be made of zirconium.
[0021] "Halide-resistant part" is made of material that is hardly corroded or is not corroded
at all by the halide and liberated halogen present in the light-transmitting ceramic
discharge vessel, while the high-pressure discharge lamp is operating. The halide-resistant
part is made of, for example, tungsten or molybdenum. In the case that the distal
of the halide-resistant part extends into the light-transmitting ceramic discharge
vessel and forms an electrode part, tungsten which excels in heat resistance is most
preferred for the halide-resistant part. The high-pressure discharge lamp according
to the present invention can be either an AC-driven lamp or a DC-driven lamp. In the
case of an DC-driven, high-pressure discharge lamp, anodes which are formed separately
may be connected to the tips of the halide-resistant part of the power-supplying conductor.
[0022] A narrow gap is provided between the halide-resistant part and the inner surface
of the small-diameter cylindrical section. While the lamp is being lighted, the residual
halide in the form of liquid flows into this gap, forming the coldest part. The gap
may be adjusted appropriately, thereby to set the coldest part can be set at a desired
temperature.
[0023] The narrow gap formed between the halide-resistant part and the inner surface of
the small-diameter cylindrical section can be provided in each side of both the power-supplying
conductors. It suffices that the narrow gap should be provided in at least one side
of the power-supplying conductors.
(Electrode)
[0024] The electrodes are provided respectively at the distal ends of the halide-resistant
parts of the power-supplying conductors. The distance d1, between the distal end of
the electrode and the inner surface of the bulging section of the light-transmitting
ceramic discharge vessel in the plane perpendicular to the axis of the electrode including
its distal end is defined to 1.0 mm or more. Since the electrode may be more or less
inclined to the axis of the light-transmitting ceramic discharge vessel in some cases,
the average distance around the circumference about the axis of the electrode is taken
as the distance.
[0025] The distance d1 can be securely maintained around the electrode by one or both of
a measure in which the length of the projection of the electrode projected into the
bulging section of the discharge vessel is increased and a method in which a portion
of the light-transmitting ceramic discharge vessel facing the electrode is enlarged.
[0026] Further, the distal end of the halide-resistant part of the power-supplying conductor
is projected to the inside of the bulging section of the light-transmitting ceramic
discharge vessel, so that the electrodes can be formed integral with the power-supplying
conductor. In this structure, the halide-resistant part of the power-supplying conductor
can be formed of a tungsten bar. As a result, functionally, the power-supplying conductor
and the electrode can be formed with the seal part and the above described tungsten
bar, therefore, the structure of the power-supplying conductor and the electrode can
be simplified and downsized.
[0027] In the present invention, it is also possible that the power-supplying conductor
and the electrode are formed individually and the electrode is connected to the distal
end of the halide-resistant part of the power-supplying conductor.
(Seal Made of Ceramic-Sealing Compound)
[0028] The seal made of ceramic-sealing compound is applied to the end of each small-diameter
cylindrical section, between the seal part and the small-diameter cylindrical section.
While the small-diameter cylindrical section is melted by heat, ceramic-sealing compound
is flowed into the gap between the seal part and the small-diameter cylindrical section,
and seals the seal part and the section in airtight fashion. The seal secures the
power-supplying conductor at a predetermined position.
[0029] It is desired that the seal part inserted in the small-diameter cylindrical section
should be completely covered with the above-mentioned ceramic-sealing compound. Moreover,
the proximal portion of the halide-resistant part, which is connected to the seal
part, may also be covered with the seal over a short distance. If so, the seal part
will hardly be corroded by halide.
(Discharge Medium)
[0030] The discharge medium contains a metallic halide. The metal includes at least a light-emitting
metal.
[0031] The halogen forming the metallic halide can be one or more selected from the group
consisting of iodine, bromine, chlorine and fluorine.
[0032] The halide of light-emitting metal can be selected from the known metallic halides
in accordance with the size and input power of the light-transmitting ceramic discharge
vessel, so as to acquire desired luminescent characteristics, such as luminous color,
general color rendering index Ra, luminous efficiency, and the like. The halide may
be one or more selected from the group of halides of, for example, sodium Na, lithium
Li, scandium Sc, and rare-earth metal.
[0033] Mercury can be contained, as a buffer medium, in an appropriate amount. Instead of
mercury, a halide of metal such as aluminum, which has a relatively high vapor pressure
and which emits a small amount of light in the visible-light region or does not emit
light at all, may be contained in the vessel.
[0034] Argon, xenon, neon, and the like can be used as rare gas.
(Other Structure)
[0035] In general, rated electric power consumption of 35W or less is preferred for the
high-pressure discharge lamp according to the present invention. In order to further
downsize the high-pressure discharge lamp, rated electric power consumption of 20W
or less is preferable.
(Effects of the Present Invention)
[0036] In the high-pressure discharge lamp according to the present invention, a sufficient
space can be maintained around the distal ends of the electrodes by using the above
described structure. As a result, when vapor of fillings coheres to the narrow gaps
as the coldest parts present in the small-diameter cylindrical sections of the light-transmitting
ceramic discharge vessel while the lamp being lighted, a turbulent flow can be prevented
from occurring around the electrodes. Even if the turbulent flow is generated, it
can be suppressed to a very low degree. Therefore, the fillings can not easily adhere
to the distal ends of the electrodes, so lowering of the electric discharging performance
of the electrodes is prevented. As a result, deterioration of starting characteristic
caused by the lowering of the electric discharging performance of the electrodes can
be prevented.
[0037] In this respect, it has been confirmed by experimentations that if the distance d1
is less than 1.0 mm, a turbulent flow can be easily generated around the electrodes
when the light is turned off.
[0038] The second high-pressure discharge lamp of the present invention which depends on
the first high-pressure discharge lamp is characterized in that: the distance d1 between
each of distal ends of the electrodes and the inner surface of the light-transmitting
ceramic discharge vessel on a plane perpendicular to an axis of the light-transmitting
ceramic discharge vessel including the distal ends of the electrodes is 1.2 mm or
more.
[0039] The second high-pressure discharge lamp has more appropriate efficiency than the
first high-pressure discharge lamp.
[0040] The third high-pressure discharge lamp according to the present invention is characterized
by comprising: a light-transmitting ceramic discharge vessel having an internal volume
of 0.1 cc or less and including a bulging section and small-diameter cylindrical sections
communicating with both ends of the bulging section, the bulging section having both
ends narrowed by a continuous curved surface, and the small-diameter cylindrical sections
having an inner diameter smaller than the bulging section; power-supplying conductors
each including a seal part and a halide-resistant section having a proximal end connected
to a distal end of the seal part and inserted respectively in the small-diameter cylindrical
sections of the light-transmitting ceramic discharge vessel, each of the halide-resistant
sections forming a slight gap to the inner surface of the small-diameter cylindrical
section; a pair of electrodes respectively arranged at the distal ends of one halide-resistant
parts and having distal ends projected by 1.2 mm or more into the bulging section
of the light-transmitting ceramic discharge vessel; seals made of ceramic-sealing
compound respectively making sealing between the small-diameter cylindrical sections
of the light-transmitting ceramic discharge vessel and the seal parts of the power-supplying
conductors; and a discharge medium containing metallic halide and filled in the light-transmitting
ceramic discharge vessel.
[0041] In the present invention, the length of the projection of the electrode projected
into the bulging section is defined as follows. The length of the bulging section
is the distance between cross-points where the axis of the light-transmitting ceramic
discharge vessel crosses lines which are tangent to inner surfaces of the small-diameter
cylindrical sections in both end sides and are extended from the center of the inner
surface of the bulging section. Therefore, the length of the small-diameter cylindrical
section is given by measuring the size from the center of the bulging section to an
end surface of a small-diameter cylindrical section and further subtracting the half
of the length of the bulging section from the size.
[0042] As a result, the projecting length of the distal end of the electrode is equal to
the distance from the end of the bulging section to the distal end of the electrode.
[0043] In this present invention, by defining the projecting length of the electrode projected
into the bulging section of the light-transmitting ceramic discharge vessel, a turbulent
flow around the electrodes can be suppressed when the lamp is turned off. That is,
by defining the projecting length as described above, a sufficient space is maintained
around the electrodes so that the turbulent flow can not be generated when turning
off the lamp or can be suppressed to a very low degree even if a turbulent flow is
generated.
[0044] Accordingly, the fillings hardly adheres to the electrodes and thus the starting
characteristic can be improved.
[0045] In contrast, it has been confirmed by experimentation that if the projecting length
of the distal end of the electrode is less than 1.2 mm, a sufficient space can not
be maintained around the electrodes and the starting characteristic also can not be
improved.
[0046] The fourth high-pressure discharge lamp according to the present invention is characterized
by comprising: a light-transmitting ceramic discharge vessel having an internal volume
of 0.1 cc or less and including a bulging section and small-diameter cylindrical sections
communicating with both ends of the bulging section, the bulging section having both
ends narrowed by a continuous curved surface, and the small-diameter cylindrical sections
having an inner diameter smaller than the bulging section; power-supplying conductors
each including a seal part and a halide-resistant section having a proximal end connected
to a distal end of the seal part and inserted respectively in the small-diameter cylindrical
sections of the light-transmitting ceramic discharge vessel, each of the halide-resistant
sections forming a slight gap to the inner surface of the small-diameter cylindrical
section; a pair of electrodes respectively arranged at the distal ends of one halide-resistant
parts and having distal ends projected by 1.2 mm or more into the bulging section
of the light-transmitting ceramic discharge vessel, with a distance d1 of 1.0 mm or
more maintained between each of distal ends of the electrodes and the inner surface
of the light-transmitting ceramic discharge vessel on a plane perpendicular to an
axis of the light-transmitting ceramic discharge vessel including the distal ends
of the electrodes; seals made of ceramic-sealing compound respectively making sealing
between the small-diameter cylindrical sections of the light-transmitting ceramic
discharge vessel and the seal parts of the power-supplying conductors; and a discharge
medium containing metallic halide and filled in the light-transmitting ceramic discharge
vessel.
[0047] This invention defines the length of the projection of the distal end of the electrode
projected into the bulging section and the distance between the distal end of the
electrode and the inner surface of the discharge vessel in the plane perpendicular
to the axis of the light-transmitting ceramic discharge vessel, as above described,
thereby to maintain a space around the electrodes.
[0048] The fifth high-pressure discharge lamp of the present invention, according to any
one of the first to third high-pressure discharge lamps, is characterized in that
the light-transmitting ceramic discharge vessel has an inner volume of 0.05 cc or
less.
[0049] The present invention provides a more remarkable effect in case of a small, high-pressure
discharge lamp in which the light-transmitting ceramic discharge vessel has an inner
volume of 0.05 or less. The inner volume can be reduced to less than 0.04 cc.
[0050] Further, it is effective if the rated lamp power of the high-pressure discharge lamp
is set to of 20W or less.
[0051] A lighting apparatus according to the present invention is characterized by comprising:
a main body; and any one of the first to fifth high-pressure discharge lamps, supported
by the main body.
[0052] In the present invention, the lighting apparatus conceptually covers all apparatuses
that apply light emission of a high-pressure discharge lamp for any purposes. For
example, the present invention is applicable to lighting apparatuses, headlights for
mobiles, light sources for optical fibers, image projection apparatuses, photochemical
apparatuses, fingerprint identification apparatuses, and the like.
[0053] The main body means the other part of the lighting apparatus than the high-pressure
discharge lamp.
[0054] A preferred example of application of the present invention in addition to the above
cases is a bulb type high-pressure lamp. In the present invention, "bulb type high-pressure
discharge lamp" means a lighting device which integrally comprises a high-pressure
discharge lamp, a discharge lamp lighting device, and a power-receiver means such
as a base and which can be turned on by merely setting it in a lamp socket for an
incandescent lamp, like a bulb-type fluorescent lamp.
[0055] Since the present invention uses a small, high-pressure discharge lamp which has
a small light-emitting section and can easily control light, a reflector should preferably
be comprised integrally when forming a bulb-type discharge lamp.
[0056] In this case, it is possible to attain a down light which can be directly attached
to a lighting tool for a down light or so with an excellent light-distribution characteristic
and which provides a high color temperature.
Brief Description of Drawings
[0057]
FIG. 1 is a sectional view showing a first embodiment of the high-pressure discharge
lamp according to the present invention.
FIG. 2 is an enlarged sectional view of a main part, showing measurement references
of respective sections of the light-transmitting ceramic discharge vessel.
FIG. 3 is a sectional view showing a second embodiment of the high-pressure discharge
lamp according to the present invention.
FIG. 4 is a sectional view showing a third embodiment of the high-pressure discharge
lamp according to the present invention.
FIG. 5 is a front view of a bulb type high-pressure discharge lamp as an embodiment
of the lighting apparatus according to the present invention, partially showing a
cross-section thereof.
Best Mode for Carrying Out the Invention
[0058] A first embodiment of the high-pressure discharge lamp according to the present invention
will be explained with reference to FIGS. 1 and 2.
[0059] In FIGS. 1 and 2, the reference numeral 1 denotes a light-transmitting ceramic discharge
vessel. The reference numeral 2 denotes power-supplying conductors. The reference
numeral 3 denotes electrodes. The reference numeral 4 denotes seals. The light-transmitting
ceramic discharge vessel includes a bulging section 1a and small-diameter cylindrical
sections. The both ends of the bulging section 1a are narrowed by continuous curved
surfaces and the bulging section 1a is formed into a hollow and substantially elliptic
spherical shape. The small-diameter cylindrical section 1b is connected to the bulging
section through the continuous curved surface, and forms the light-transmitting ceramic
discharge vessel 2 by integral molding.
[0060] Next, a measurement reference for the bulging section of the light-transmitting ceramic
discharge vessel and the small-diameter cylindrical section will be explained with
reference to FIG. 2.
[0061] Suppose that the length rL of the bulging section 1a is the distance between cross-points
P1 and P2 where lines s1 and s2 are respectively drawn in the lateral directions from
the center of the inner surface of the bulging section 1a to be tangent to the inner
surface of the bulging section 1a in the small-diameter sides.
[0062] Meanwhile, the length of the small-diameter section 1b in the left side in the figure
is defined as the distance lT1 between the end portion of the length rL of the bulging
section 1a which is the cross-point P1 and the left end surface of the small-diameter
cylindrical section (omitted from FIG. 2). Likewise, the length of the small-diameter
cylindrical section in the right side in the figure is defined as the distance lT2
between the cross-point P2 and the right end surface of the small-diameter cylindrical
section.
[0063] Accordingly, the total length of the light-transmitting ceramic discharge vessel
can be obtained found by the following equation.

[0064] The explanation will further be continued with reference to FIG. 1.
[0065] The power-supplying conductor 2 includes a seal part 2a and a halide-resistant part
2b.
[0066] The seal part 2a functions when sealing the light-transmitting ceramic discharge
vessel 1 between the power-supplying conductor 2 and the small-diameter cylindrical
section 1b. The halide-resistant part 2b has a proximal end welded to the tip of the
seal part 2a and a distal end projected into the bulging section 1a. Further, a small
gap is formed between the part 2b and the inner surface of the small-diameter cylindrical
section as shown in FIG. 2. The electrode 3 is connected to the halide-resistant part
2b and is constructed to be integral with the power-supplying conductor 2.
[0067] The dimensional relation between the distal end of the electrode 3 and the inner
surface of the bulging section 1a will be explained again with reference to FIG. 2.
[0068] Where d1 is the distance between the distal end of the electrode 3 and the inner
surface of the light-transmitting ceramic discharge vessel 1 on a plane perpendicular
to the axis c of the light-transmitting ceramic discharge vessel 1 including the distal
end, this d1 is set to 1.0 mm or above.
[0069] In addition, the projection length d2 by which the electrode 3 projects from the
bulging section 1a of the light-transmitting ceramic discharge vessel 1 is set to
1.2 mm or above.
[0070] A seal 4 is inserted between the small-diameter cylindrical section 1b and the seal
part 2a to seal airtightly the light-transmitting ceramic discharge vessel 1 and fixes
the power-supplying conductor 2 to a predetermined position. To form the seal 4, a
ceramic-sealing compound is applied around the seal part 2a of the power-supplying
conductor 2 and is heated and melted to enter into the narrow gap between the seal
part 2a and the inner surface of the small-diameter cylindrical section 1b. Further,
the whole of the seal part 2a inserted in the small-diameter cylindrical section 1b
is covered with the ceramic-sealing compound, and the proximal end of the halide-resistant
section 2b is further covered as well.
[0071] A discharge medium containing a metallic halide of light-emitting metal and a rare
gas is filled in the light-transmitting ceramic discharge vessel.
[0072] The high-pressure discharge lamp shown in FIG. 1 is specified as follows.
[0073] The light-transmitting ceramic discharge vessel is made of YAG and has the bulging
section 1a having a length of 6 mm long and thickness of 0.5 mm, and the small-diameter
cylindrical section 1b having an outer diameter of 1.8 mm and a total length being
35 mm.
[0074] In the power-supplying conductor, the seal part 2a is a niobium bar having an outer
diameter of 0.64 mm, and the halide-resistant section 2b (the electrode as well) is
a tungsten bar having an outer diameter of 0.3 mm.
[0075] The discharge medium contains 0.6 mg of, 0.6 mg of TlI, 0.4 mg InI and mercury 5
mg, and approximately 20 kPa of argon is filled as a relaxation gas.
[0076] Next, the length of the projection d2 of the electrode projected into the bulging
section of the light-transmitting ceramic discharge vessel is set to 2 mm, and twenty
high-pressure discharge lamps are manufactured, wherein the distance d1 between the
distal of the electrode and the inner surface of the light-transmitting ceramic discharge
vessel is changed within and beyond the scope of the present invention. The following
Table 1 shows a result of comparing the probabilities of starting errors thereof using
a discharge lamp lighting circuit (non-loaded secondary voltage: 4.5 kV).
Table 1
| Distance d1 (mm) |
Starting Error Probability (%) |
| 0.4 |
100 |
| 0.6 |
95 |
| 0.8 |
55 |
| 1.0 |
0 |
| 1.2 |
0 |
| 1.4 |
0 |
[0077] FIG. 3 is a sectional view showing a second embodiment of the high-pressure discharge
lamp according to the present invention. In FIG. 3, the same parts as those in FIG.
1 are designated at the same reference numerals as those used to designate the same
parts, and detailed description of those parts will be omitted herefrom.
[0078] The present embodiment differs from the first embodiment in that the bulging section
1a of the light-transmitting ceramic discharge vessel 1 is formed into an elliptical
spherical shape to enlarge the distance between the electrodes relatively.
[0079] FIG. 4 is a sectional view showing a third embodiment of the high-pressure discharge
lamp according to the present invention. In the figure, the same parts as those in
FIG. 1 are designated at the same reference numerals as those in FIG. 1, and detailed
description of those parts will be omitted herefrom.
[0080] The present embodiment is different in that the high-pressure discharge lamp is not
sealed in an outer tube but is constructed in a structure suitable for lighting.
[0081] That is, the seal part 2a of the power-supplying conductor is not structured to be
exposed in the air, because the seal part 2a of the power-supplying conductor can
be easily oxidized. A platinum bar 5 is welded to the end of the seal part 2a and
the first seal 4 is formed. Thereafter, a ceramic tube 4 is engaged on the portion
of the seal part 2a which is exposed to the outside from the seal 4. A ceramic-sealing
compound is applied to the end of the ceramic tube 5 and is melted with heat to form
a second seal 7.
[0082] The seal part 1a positioned outside the light-transmitting ceramic discharge vessel
1 is coated airtightly by the ceramic tube 6 and the second seal 7 so that the high-pressure
discharge lamp can be lighted in the air without sealing it air-tightly in the outer
tube.
[0083] Further, the length of the small-diameter cylindrical section differs between the
sections 1b and 1b' in the present embodiment.
[0084] FIG. 5 is a partially cutaway central front view showing a bulb type high-pressure
discharge lamp as an embodiment of a lighting apparatus according to the present invention.
In the figure, the same parts as those in FIG. 1 are designated at the same reference
numerals, and detailed description of those parts will be omitted herefrom.
[0085] The bulb type high-pressure discharge lamp according to the present embodiment comprises
a high-pressure lamp device 11, a discharge lamp lighting device 12, a power-receiver
means 13 and a case 14. The high-pressure discharge lamp device 11 includes a high-pressure
lamp 11a and a reflector 11b. Although this high-pressure discharge lamp 11a uses
a high-pressure discharge lamp according to the present invention, the lamp shown
in FIG. 4 is particularly preferred in this case.
[0086] The reflector 11b includes a light-projection opening 11b1, a reflecting surface
11b2 and a top opening 11b3. The small-diameter cylindrical section 1b in the top
side is fixed to the top opening 11b3 with an inorganic adhesive 11c, thereby supporting
the high-pressure discharge lamp 11a, in a manner that the bulging section of the
high-pressure discharge lamp 11a substantially corresponds to the focus of the reflector
11b. Since the small-diameter cylindrical section 1b' of the light-transmitting ceramic
discharge vessel provided in the high-pressure discharge lamp does not project forward
from the light-projection opening 11b1 of the reflector 11b, light distribution is
not disturbed.
[0087] The discharge lamp lighting device 12 includes a high frequency inverter and a current
limiter means, and lights the high-pressure discharge lamp 11a. The discharge lamp
lighting device 12 is provided in the back side of the reflector 11b of the high-pressure
discharge lamp 11a. The heat caused by lighting of the high-pressure discharge lamp
11a is shielded by the reflector 11b so that the discharge lamp lighting device 12
operates stably.
[0088] The power-receiver means 13 is formed of a screw base and receives electricity thereby
energizing the discharge lamp lighting device 12, when the screw base is attached
to a lamp socket (not shown).
[0089] Although the case 14 stores the structural elements described above to hold them
at predetermined positions, the case 14 has a streamlined part which increases its
applicability to lighting devices such as a down light and the like.
Industrial Applicability
[0090] According to the present invention, there is provided a small, high-pressure discharge
lamp which starts operation easily, allows easy transition from glow discharge to
arc discharge, and prevents blackening of the light-transmitting ceramic discharge
vessel caused by sputtering.