[0001] The present invention relates to a miniature incandescent lamp and, more particularly,
to an improvement in lamp characteristics.
[0002] Basic requirements for miniature incandescent lamps used in cars or the like are
luminous efficacy (Im/ W) and increased life expectancy. It is ideal to increase the
luminous efficacy and prolong the life of the lamp. However, in a conventional miniature
incandescent lamp, when the luminous efficacy is increased, its life is shortened.
This is because filament evaporation becomes active when a filament temeprature is
increased to increase the luminous flux, thereby disconnecting the filament at an
early period and blackening the bulb wall.
[0003] In a covnentional lamp, an inert gas is filled in a bulb to decrease filament evaporation,
and a greater effect can be obtained when the molecular weight of the filled gas is
larger. For example, a filament temperature of a lamp sealing krypton gas can be higher
than that of a lamp filling argon gas and has a lower filling gas loss than the lamp
filling argon gas. In addition, when xenon is mixed with krypton, the above-mentioned
effect can be typically reinforced, as described in Japanese Utility Model Publication
No. 54-2068.
[0004] Xenon has a lower ionization voltage than those of argon and krypton. When a high
content of xenon is filled in the bulb, an arc discharge occurs between coil turns
of the filament, and the filament is burnt out. In a general-purpose illumination
incndescent lamp having ratings of 100 V (100 W) and described in the above publication,
the ratio of xenon to krypton is reduced to 5 to 10.4% by volume. In addition, nitrogen
is mixed in a gas mixture of krypton and xenon to increase an arc discharge starting
voltage. However, when the xenon content is low and the content of nitrogen is high,
the effect of xenon is impaired.
[0005] Demand has arisen for a miniature incandescent lamp to obtain the effect of xenon,
to provide high luminous efficacy and increased life expectancy properties, and to
prevent an arc discharge in the lamp.
[0006] A conventional halogen lamp is known as an incandescent lamp having high luminous
efficacy and long life. However, the bulb wall temperature must be increased to activate
the halogen cycle in the halogen lamp. For this purpose, hard glass such as quartz
or aluminosilicate glass having high heat resistance must be used as a bulb material.
However, hard glass is expensive and is difficult to work with. In particular, when
a miniature lamp has a lamp power of less than 8 W, the bulb must be extremely minuaturized
to increase the bulb wall temperature. As a result, the manufacturing process becomes
complicated, and hard glass, which is difficult to work with, cannot be used. In addition,
when the lamp size is decreased, it is difficult to control and fill the proper amount
of halogen gas in the lamp. When the lamp is minuaturized, the filament coil wire
must be thinner. The life of the lamp becomes shortened due to a chemical reaction
between the halogen gas and the thin coil wire. Therefore, a miniature halogen lamp
involves difficult manufacturing techniques and results in high cost.
[0007] US--A-2 891 189 discloses an gas-filled electric incandescent lamp filled with nitrogen
and xenon, wherein the xenon may be pure xenon or a gas mixture containing xenon as
an constituent of at least about 80% by volume. One feature of this prior art lamp
is that the minimum distance between the nearest points of highest potential difference
of the filament depends on the rated voltage of the lamp, the rated energy consumption
of the lamp, the luminous efficiency and a certain numerical factor.
[0008] US-A-4 208 609 discloses an incandescent lamp in which a ratio defined by the center
to center spacing of the turns of the filament, divided by the diameter of the filament
is between 1,4 and 1,8. If this ratio is transformed to a value defined by the spacing
between facing sides of two adjacent turns of the filament, divided by the diameter
of the filament, there is obtained a value between 0.4 and 0.8.
[0009] However, if a gas having a low arc discharge starting voltage is used, arc discharge
instantly takes place between turns when the above ratio is in the range of 0,4 to
0,8.
[0010] The object of the present invention is to provide a miniature incandescent lamp,
which shows high luminous efficacy and long life and which prevents an arc discharge
between turns of a coiled filament.
[0011] A miniature incandescent lamp of the present invention comprises a glass bulb containing
an inert gas therein and a coiled filament arranged in the bulb. The inert gas contains
xenon and nitrogen. A content of xenon in the inert gas is 80% b volume or more. A
pitch ratio p/d of a coil pitch (spacing between two adjacent coil turns) p to a wire
diameter d is 1.4 or more.
[0012] When the content of xenon is less than 80% by volume, the effect of xenon cannot
be obtained, and a lamp have high luminous efficacy and long life cannot be obtained.
[0013] The xenon content preferably falls within the range of 90 and 98% by volume.
[0014] A nitrogen content preferably falls within the range of 2 and 10% by volume so as
to obtain the effect of xenon and prevent the arc discharge.
[0015] When the ratio p/d is larger, the effect of preventing the arc discharge can be improved.
However, in practice, the upper limit of the pitch ratio is 2.0. The ratio p/d preferably
falls within the range of 1.4 and 1.8.
[0016] The inert gas filled in the lamp of the present invention is not limited to xenon
and nitrogen. The inert gas may contain argon and/or krypton.
[0017] The application of the lamp according to the present invention is not limited to
use in vehicles but can be extended to decorative illuminations for home use.
[0018] The lamp base is not limited to be of a wedge type but can be of an Edison type.
[0019] A material for the lamp bulb according to the present invention may comprise soft
glass or hard glass. A large amount of xenon having high molecular weight (i.e., a
low thermal conductivity coefficient) is filled in the bulb of the lamp of the present
invention, so that low-cost soft glass having good workability can be adapted.
[0020] This invention can be more fully understood from the following detailed description
when taken in conjunction with the accompanying drawings, in which:
Fig. 1 is a perspective view of a wedge base type miniature incandescent lamp;
Fig. 2 shows a filament of the lamp shown in Fig. 1; and
Fig. 3 is a graph showing the relationship between the ratio p/d of a coil pitch p
to a wire diameter d and the arc discharge starting voltage.
[0021] A miniature incandescent lamp shown in Fig. 1 comprises a wedge base type lamp having
ratings of 12 V (5 W). A bulb 1 comprises soft glass such as lead glass or soda-lime
glass. A tungsten filament 2 is mounted in the bulb 1 and is connected to lead wires
3. The lead wires 3 are sealed at a pinch-sealed portion 4 and extend outside therefrom.
Lead-out portions 6 of the lead wires 3 are folded along the side surfaces of the
pinch sealed portion 4. The central portion of the filament 2 is supported by an anchor
wire 5.
[0022] A gas mixture of xenon gas and nitrogen gas, which has a volume ratio of 95:5, is
filled in the bulb 1 at a total pressure of 79992 Pa (600 Torr).
[0023] The filament 2 comprises a single coil made of a tungsten wire. A ratio p/d of a
coil pitch (spacing between coil turns) p (mm) to a wire diameter d (mm) shown in
Fig. 2 is given as 1.8.
[0024] The specifications of the lamp of the present invention and the conventional miniature
incandescent lamp are summarized below.

[0025] As is apparent from the above table, the color temperature , luminous flux and life
of the miniature incandescent lamp of the present invention are better than those
of the conventional lamp.
[0026] When 100% of xenon gas is filled in the bulb, the convection loss of the gas is decreased,
so that the luminous flux after 100 hours can be more than 70 lm. As previously described,
however, xenon has a low ionization voltage, and an arc discharge tends to occur between
the coil turns of the filament. For example, when a 12 V, 5 W type lamp is used, an
arc discharge starting voltage becomes as low as 14.5 V (ratio at the rated voltage
is 1.2). However, when the volume content of xenon gas in the filling gas becomes
less than 80%, the arc discharge starting voltage is increased. The luminous flux
after 1,000 hours becomes 55 lm or less. In this manner, the effect of xenon gas is
extremely impaired.
[0027] According to the present invention, the volume % of xenon gas is kept at 80% or more,
and the effect of xenon gas is maintained. In addition, nitrogen gas is mixed in xenon
gas and the ratio p/d of the coil pitch p to the wire diameter d is kept to be 1.4
or more, thereby preventing a decrease in the arc discharge starting voltage.
[0028] The present inventors made an experiment to clarify the relationship between the
ratio p/d and the arc discharge starting voltage in a 12 V, 5 W type miniature incandescent
lamp. Results are shown in Fig. 3.
[0029] As is apparent from the graph in Fig. 3, it is found that the arc discharge starting
voltage becomes sufficiently high when the ratio p/d us 1:4 or more. However, when
the ratio p/d becomes less than 1.4, the electric field strength between the coil
turns is increased, so that the arc discharge tends to occur. As described above,
when the ratio p/d is 1.4 or more, however, the electric field strength between the
coil turns is descreased. As a result, the arc discharge will not substantially occur.
[0030] As has been described above, according to the miniature incandescent lamp of the
present invention, since the inert gas contains 80% by volume or more of xenon, the
gas loss becomes small and the liminous efficacy is improved. The filament evaporation
of the lamp can be decreased to provide long life. Furthermore, nitrogen is mixed
in xenon, and the ratio p/d of the filament is 1.4 or more. Therefore, the arc discharge
will not occur between the turns of the coiled filament. Soft glass is used as the
bulb material, so that the lamp can be easily manufactured at low cost.
1. A miniature incandescent lamp comprising a glass bulb (1) containing an inert gas
therein and a coiled filament (2) arranged in said bulb (1), the inert gas containing
xenon and nitrogen, the content of xenon in the inert gas being not less than 80%
by volume, characterized in that the pitch ratio p/d of the spacing p between two
adjacent turns of the coiled filament (2) to the wire diameter d is not less than
1.4.
2. A lamp according to claim 1, characterized in that the content of xenon falls within
the range of 90% by volume to 98% by volume.
3. A lamp according to claim 1 or 2, characterized in that the content of nitrogen
falls within the range of 2% by volume to 10% by volume.
4. A lamp according to claim 1, 2 or 3, characterized in that the inert gas further
contains at least one material selected from the group consisting of argon and krypton.
5. A lamp according to any of claims 1 to 4, characterized in that the ratio p/d falls
within the range of 1.4 to 2.0.
6. A lamp according to claim 5, characterized in that the ratio p/d falls within the
range of 1.4 to 1.8.
7. A lamp according to any of claims 1 to 6, characterized in that said bulb comprises
soft glass.
1. Miniaturglühlampe, umfassend eine ein inertes Gas enthaltende Glasbirne (1) und
einen in der Birne (1) angeordneten, gewickelten Faden (2), wobei das inerte Gs Xenon
und Stickstoff enthält und der Anteil von Xenon in dem inerten Gas nicht weniger als
80 Vol.-% beträgt, dadurch gekennzeichnet, daß das Teilungerverhältnis p/d des Abstands
p zwischen zwei benachbarten Windungen des gewickelten Fadens
(2) und dem Drahtdurchmesser d nicht weniger als 1,4 beträgt.
2. Lampe nach Anspruch 1, dadurch gekennzeichnet, daß der Xenon-Anteil in den Bereich
von 90 Vol.-% bis 98 Vol.-% fällt.
3. Lampe nach Anspruch 1 oder 2, dadurch gekennzeichnet, daß der Stickstoffanteil
in den Bereich von 2 Vol.-% bis 10 Vol.-% fällt.-4. Lampe nach Anspruch 1, 2 oder
3, dadurch gekennzeichnet, daß das inerte Gas weiterhin mindestens ein Material enthält,
das aus der aus Argon und Krypton bestehenden Gruppe ausgewählt ist.
5. Lampe nach einem der Ansprüche 1 bis 4, dadurch gekennzeichnet, daß das Verhältnis
p/d in den Bereich von 1,4 bis 2,0 fällt.
6. Lampe nach Anspruch 5, dadurch gekennzeichnet, daß das Verhältnis p/d in den Bereich
von 1,4 bis 1,8 fällt.
7. Lampe nach einem der Ansprüche 1 bis 6, dadurch gekennzeichnet, daß die Birne Weichglas
enthält.
1. Lampe à incandescence miniature comprenant une ampoule de verre (1) contenant un
gaz inerte et un filament spiralé (2) disposé dans ladite ampoule (1), le gaz inerte
contenant du xénon et de l'azote, la teneur en xénon du gaz inerte n'étant pas inférieure
à 80% en volume, caractérisé en ce que le rapport d'écartement p/d de l'écartement
p entre deux spires adjacentes du filament spiralé (2) au diamètre d du fil n'est
pas inférieur à 1,4.
2. Lampe selon la revendication 1, caractérisée en ce que la teneur en xénon s'établit
dans l'intervalle de 90% en volume à 98% en volume.
3. Lampe selon la revendication 1 ou 2, caractérisée en ce que la teneur en azote
s'établit dans l'intervalle de 2% en volume à 10% en volume.
4. Lampe selon la revendication 1, 2 ou 3, caractérisée en ce que le gaz inerte contient
en outre au moins une matière choisie dans le groupe formé de l'argon et du krypton.
5. Lampe selon l'une quelconque des revendications 1 à 4, caractérisée en ce que le
rapport p/d s'établit dans les limites de 1,4 à 2,0.
6. Lampe selon la revendication 5, caractérisée en ce que le rapport p/d s'établit
dans les limites de 1,4 à 1,8.
7. Lampe selon l'une quelconque des revendications 1 à 6, caractérisée en ce que l'ampoule
est constituée de verre tendre.