JP2005532664A - Gas discharge headlamp for vehicles - Google Patents

Abstract

A gas discharge headlamp for a vehicle is disclosed. The headlamp includes a glass enclosure, a first discharge unit that is formed in the glass enclosure and provides a high beam, and a second discharge unit that is formed in the glass enclosure and provides a low beam. An insulating tube connected to a lead wire extended from the first and second ground electrodes of the first and second discharge means and connected to an external ground power source is connected to the glass enclosure to reflect the lamp. And a base for placement in the opening in the plate. Each discharge chamber of the first and second discharge means emits two different hues or the same hue. Therefore, by selectively supplying current to the first and second discharge means without a conventional electromechanical device, switching of the light beam between upward and downward can be realized.

Description

  The present invention relates to a gas discharge headlamp for a vehicle, and more particularly, provides a downward-upward function using a light source instead of a downward-upward drive system using electric and pneumatic pressure of a vehicle headlamp. Since there are no electromechanical devices for adjusting the downward-upward direction of the lamp by arranging a plurality of discharge vessels that emit two different hues or the same hue in one glass enclosure, For vehicles that can improve productivity and product reliability by simplifying the control structure by fundamentally or fundamentally removing defects and using a light source to achieve downward-upward, etc. The present invention relates to a gas discharge headlamp.

Generally, a vehicle is provided with a headlamp in order to ensure a driver's front view when driving in a dark place such as a night or a tunnel.
Vehicle headlamps are classified into halogen lamps and gas discharge lamps depending on the lighting system.

FIG. 1 is a side view showing a conventional gas discharge lamp for a vehicle. As shown in FIG. 1, the gas discharge headlamp is formed between an outer cover tube 10, inner sealing portions 15 and 16 formed inside the outer cover tube 10, and the inner sealing portions 15 and 16. , A discharge chamber 12 filled with a discharge gas, a pair of discharge electrodes 17 and 18 each having an end disposed in the discharge chamber 12 at a predetermined interval, and one end disposed in the internal sealing portions 15 and 16. Are connected to the other ends of the discharge electrodes 17 and 18, respectively, and lead wires 21 and 22 installed in the internal sealing portions 15 and 16 and connected to the other ends of the metal foils, respectively. A ground conductor 31 having one end connected to the upper end of the lead wire 22, an insulating tube 30 surrounding the outer peripheral surface of the ground conductor 31, and a base 50 coupled to the outer cover tube 10 and the ground conductor 31. It is made from etc..
This type of gas discharge lamp is provided for use in a vehicle lighting device such as a headlamp, and has a base 50 as described above. The base 50 can be formed in various shapes. The base 50 arranges a lamp in an opening in a reflector (not shown).

The cover tube 10 is coupled to the base 50 and has a discharge chamber 12 at the central portion. The discharge chamber 12 is composed of a hollow portion 13 filled with a gas, particularly xenon, mercury and, if necessary, a metal halide.
The two discharge electrodes 17 and 18 protrude into the hollow portion 13, and the discharge chamber 12 is connected to the tubular extensions 15 and 16.

A lead wire 21 for the discharge electrode 17 is disposed in the extension portion on the base 50 side, that is, the inner sealing portion 15, and the extension portion on the opposite side of the inner sealing portion 15, that is, the inner sealing portion 16 is connected to the discharge electrode 18. Connected lead wires 22 are arranged. In order to connect the lead wires 21 and 22 to the discharge electrodes 17 and 18, a metal foil 19 preferably made of molybdenum is disposed between the discharge electrodes.
The cover tube 10 is made of a glass tube, and is used for protecting the discharge chamber 12 and shielding UV light generated during operation of the gas discharge lamp.

The conventional gas discharge headlamp constructed in this way realizes a downward lamp or an upward lamp in a single discharge vessel, respectively, and uses a magnetic reflection or a motor to adjust the lamp downward or upward. Realized low beam.
This downward or upward operation system acts as a factor causing electrical or mechanical defects in the magnetic or motor system, reducing the reliability of the product, and single discharge of the downward and upward lamps By realizing the same color of the container, there is a problem that it is impossible to satisfy the various needs of consumers for the hue of the beam.

  Accordingly, the present invention is to solve the problems of the prior art, and its purpose is to use a light source instead of a downward-upward drive system using electric and pneumatic pressure of a vehicle headlamp. -Displacement of lamps by providing two upwards functions to emit two different hues or the same hue in a single glass enclosure;-Source of electromechanical defects that regulate upwards- Another object of the present invention is to provide a gas discharge headlamp for a vehicle that can be removed and the productivity and cost can be reduced by simplifying the structure.

  In order to achieve the above object, the present invention provides a glass enclosure that hermetically seals the interior, and a power source that is formed inside the glass enclosure and is applied via a first power electrode and a first ground electrode. A first discharge means for providing a high beam by discharging; and a second discharge for providing a low beam by being discharged by a power source formed through the second power supply electrode and the second ground electrode. And an insulating tube having one end connected to the lead wire extended from the first and second ground electrodes of the first and second discharging means and the other end connected to an external ground power supply end, and the glass There is provided a gas discharge headlamp for a vehicle having an enclosure connected thereto and a base for arranging the lamp in an opening in a reflector.

  The first discharge means or the second discharge means includes a pair of internal sealing portions, a discharge chamber formed between the internal sealing portions and having a hollow portion filled with a discharge gas, and each end portion of the discharge chamber. A pair of discharge electrodes installed at a predetermined interval, and a pair of metal foils, one end of which is connected to the other end of the discharge electrode, and a pair of metal foils that are respectively connected to the other end of the discharge electrode. A lead wire connected to the other end of the metal foil and drawn to the outside of the inner sealing portion, the inner sealing portion of the first discharging means, and the inner sealing portion of the second discharging means to the insulating tube side A plurality of conductive sleeves for crimping and welding each of the lead wires drawn out to the glass enclosure, and supporting and fixing the inner sealing portion of the first discharging means and the inner sealing portion of the second discharging means to the glass enclosure, respectively. Including the support of There.

Hereinafter, the present invention will be described in detail with reference to the accompanying drawings. In the present specification and drawings, constituent elements having substantially the same functional configuration are denoted by the same reference numerals.
FIG. 2 is a sectional view showing a gas discharge headlamp for a vehicle according to the present invention. As shown in the figure, the gas discharge headlamp for a vehicle according to the present invention is composed of a glass enclosure 101 containing a discharge member and the glass enclosure 101, and the lamp is connected to a reflector 180 (FIGS. 3 and 4) and a base 170 for fixed installation in the opening inside.

  The glass encapsulant 101 has a discharge assembly inside, but is discharged by a power source applied through a first power electrode 115 and a first ground electrode 116 extended from a base 170 to provide a high beam. A first discharge unit 110; a second discharge unit 120 formed inside the glass enclosure 101, which discharges by a power source applied through a second power electrode 125 and a second ground electrode 126 to provide a low beam; Conductors 141 connected in common to the lead wires 119 and 129 extending from the first ground electrode 116 and the second ground electrode 126 of the first and second discharge means 110 and 120 and connected to an external ground power supply terminal are provided. It consists of a built-in insulating tube 140.

  The first discharge means 110 includes an inner sealing portion 113 and 114, a discharge chamber 111 formed between the inner sealing portions 113 and 114, and a hollow portion 112 filled with a discharge gas, and each of the discharge chambers 111. A pair of discharge electrodes whose ends are disposed at a predetermined interval, that is, a first power electrode 115 and a first ground electrode 116, are disposed in the internal sealing portions 113 and 114, and one end is the first power electrode 115 and A pair of metal foils 117 respectively connected to the other end of the first ground electrode 116 and the inner sealing part 113 are installed in the inner sealing part 113 and connected to the other end of the metal foil 117 so as to be outside the inner sealing parts 113 and 114. The lead wires 118 and 119 are drawn out.

  The second discharge means 120 includes an inner sealing portion 123, 124, a discharge chamber 121 formed between the inner sealing portions 123, 124, and a hollow portion 122 filled with a discharge gas, and a discharge chamber 121. A pair of discharge electrodes whose ends are disposed at a predetermined interval, that is, the second power electrode 125 and the second ground electrode 126, and the inner sealing portions 123 and 124 are disposed, and one end is disposed in the second power electrode 125. And a pair of metal foils 127 connected to the other end of the second ground electrode 126 and the inner sealing parts 123 and 124, respectively, and connected to the other end of the metal foil 127 and connected to the inner sealing parts 123 and 124, respectively. And lead wires 128 and 129 drawn to the outside.

In the gas discharge headlamp according to the present invention, the lead wires 119 and 129 drawn out from the inner sealing portion 114 of the first discharge means 110 and the inner sealing portion 124 of the second discharge means 120 to the insulating tube 140 side are pressure welded. And a plurality of supports 131 for supporting and fixing the inner sealing portions 113 and 114 of the first discharging means 110 and the inner sealing portions 123 and 124 of the second discharging means 120 to the glass enclosure 101, respectively. Is further provided.
The discharge chamber 111 of the first discharge means 110 and the discharge chamber 121 of the second discharge means 120 are located at different distances from the base 170. The glass encapsulant 101 is filled with nitrogen for preventing arc generation at a low pressure. The insulating tube 140 is made of a ceramic material and is disposed in the glass enclosure 101, that is, in the same space as the first and second discharge means 110 and 120.

  In addition, the gas discharge headlamp according to the present invention is formed between the glass enclosure 101 and the base 170, and the glass enclosure 101 and the base 170 are coupled to each other so that the first discharge means 110 and the second discharge means 120 are combined. Further, a connecting member 150 made of an epoxy resin is further provided for insulating and fixing the power supply leads 118 and 128 extended from the ground and the ground conductor 141 extended through the insulating tube 140.

  That is, the first and second discharge means 110 and 120 have internal sealing portions 113, 114, 123, and 124, and the internal sealing portions have discharge chambers 111 and 121. The hollow portions 112 and 122 of the discharge chambers 111 and 121 are filled with a gas such as xenon, mercury, or a metal halogen compound as necessary, and at least two electrodes ( Each of the power supply electrode and the ground electrode protrudes.

Next, since the first and second discharge means 110 and 120 have the same configuration, the first discharge means 110 will be mainly described.
The discharge chamber 111 has an internal sealing portion 113 connected to the hollow portion 112, and the lead wire 118 of the first power electrode 115 drawn from the base 170 is disposed in the internal sealing portion 113 on the base 170 side. The lead wire 119 connected to the first ground electrode 116 is disposed on the inner sealing portion 114 on the opposite side of the base 170.
The internal sealing portions 113 and 114 connected to the discharge chamber 111 are sealed with molybdenum metal foil 117 for fixing the electrodes and quartz glass as an insulating medium so as to withstand high pressure.

The first discharge means 110 includes internal sealing portions 113 and 114, a discharge chamber 111, a pair of discharge electrodes 115 and 116, a pair of metal foils 117, lead wires 118 and 119, an insulating tube 140, and a ground conductor 141.
The glass enclosure 101 protects the internal sealing portions 113 and 114 and the discharge chamber 111, and seals the inside and outside so that the discharge chamber 111 can maintain an appropriate temperature, thereby reducing the relative luminous sensitivity due to the temperature drop. prevent. The glass enclosure 101 is fixed to the connecting member 150.
The inner sealing portions 113 and 114 are formed inside the glass enclosure 101 and have a discharge chamber 111 in the center. The inner sealing portions 113 and 114 are made of quartz glass.

The discharge chamber 111 has a substantially elliptical shape, and is filled with a gas such as a discharge gas, xenon, mercury, or a metal halide, as necessary.
The discharge electrodes 115, 116, that is, the first power supply electrode 115 and the first ground electrode 116 are fixed at one end to the internal sealing portions 113, 114, and the other ends are installed in the discharge chamber 111 at regular intervals. The
As shown in FIG. 3, when a current is artificially supplied to the first discharge means 110 from the outside, the gas filled in the hollow portion 112 is discharged. As a result, the temperature and pressure of the gas in the hollow portion 112 increase, and an arc is generated by the gas.

  After that, when the gasified metal compound is mixed with the arc and separated into metal ions and halogen ions, a current flows, and when the temperature of the central part of the arc increases, the metal ions are strengthened in the arc. Emits light. Therefore, the light emitted from the discharge chamber 111 of the first discharge means 110 that is close to the reflector 180 is reflected from the focal center side of the reflector 180. At this time, the light is reflected almost linearly and the high beam is reflected. provide.

As shown in FIG. 4, when the current applied to the first discharge means 110 is interrupted and the current is supplied to the second discharge means 120, light is emitted from the discharge chamber 121 of the second discharge means 120 that is far from the reflector 180. Since the reflected light is reflected from the edge side while deviating from the focal center of the reflector 180, the light is refracted downward to provide a low beam.
The metal foil 117 is installed in the internal sealing portions 113 and 114, and one end is connected to the discharge electrode 115 or 116 and the other end is connected to the lead wire 118 or 119. The metal foil 117 may be made of molybdenum foil.

The lead wires 118 and 119 are mediators through which a supply current moves, and one ends of the lead wires 118 and 119 are connected to the discharge electrodes 115 and 116, respectively. The lead wire 119 is connected to the ground conductor 141, and the lead wire 118 is electrically connected to a socket terminal (not shown) of the base 170.
The ground conductor 141 has one end connected to the lead wire 119 and the other end electrically connected to a socket of the base 170. The ground conductor 141 also serves to support the glass encapsulant 101.

The internal sealing portions 113, 114, 123, 124 of the first and second discharge means 110, 120 are connected by a plurality of supports 131 installed on both sides. The support 131 is disposed at a right angle to the longitudinal direction of the inner sealing portions 113, 114, 123, and 124 and is coupled to the glass enclosure 101. The inner sealing portions 113, 114, 123, and 124 are connected to the glass enclosure. Fix and support 101.
The insulating tube 140 surrounding the outer peripheral surface of the ground conductor 141 is made of an insulating aluminum oxide Al ₂ O ₃ or steatite.
The base 170 is an adapter having a keyhole to which the discharge headlamp is attached to the reflector 180, and includes an adapter socket (not shown) attached to the other side of the keyhole.

  On the other hand, an ignition unit and a control unit (not shown) are additionally installed for the selection operation of the first and second discharge means 110 and 120. The ignition unit applies a high voltage to the electrodes of the first discharge unit 110 or the second discharge unit 120 in accordance with a control signal from the control unit. Therefore, it is possible to easily drive and control the downward lamp or the upward lamp of the headlamp by the electronic control method of the light source.

  As described above, the present invention provides two different hues or the same hue by providing a downward-upward function using a light source instead of a downward-upward driving system using electric and pneumatic pressure of a vehicle headlamp. Since there are no mechanical devices such as a magnetic device or a motor for adjusting the downward-upward direction of the lamp as compared with the conventional one, by disposing a plurality of discharge vessels that emit light in a single glass enclosure, electromechanical By removing defects from the source and using a light source to realize a down-up lamp, productivity can be improved and product reliability can be improved by simplifying the control structure. Mechanical defects can be completely eliminated and product life can be improved.

In addition, there is an advantage that various demands of consumers can be satisfied by injecting gas of different hues into the two discharge means and realizing different colors according to the downward light and the upward light. .
Although the preferred embodiments of the present invention have been described above, those skilled in the art will variously modify, add, and replace the present invention without departing from the spirit and scope of the invention disclosed in the claims. I understand that it is possible.

It is a side view which shows the gas discharge lamp for vehicles concerning a prior art. It is a side view which shows the gas discharge lamp for vehicles which concerns on this invention. FIG. 3 is a partially cut-out operation state diagram showing a state where a high beam is turned on by applying power to the first discharge means in the vehicle gas discharge lamp according to the present invention. FIG. 5 is a partially cut-off operation state diagram showing a state where a low beam is turned on by applying power to the second discharge means in the vehicle gas discharge lamp according to the present invention.

Explanation of symbols

101 Glass enclosure 111, 121 Discharge chamber 112 Hollow portion 113, 114, 123, 124 Internal sealing portion 115 First power electrode 116 First ground electrode 117, 127 Metal foil 118, 119, 128, 129 Lead wire 125 Second power source Electrode 126 Second ground electrode 131 Support body 135 Conductive sleeve 140 Insulating tube 141 Conductor 150 Connection member 170 Base 180 Reflector

Claims (6)

A glass enclosure that hermetically seals the interior;
First discharge means formed inside the glass enclosure and discharging with a power source applied through a first power electrode and a first ground electrode to provide a high beam;
A second discharge unit formed in the glass enclosure and discharged by a power source applied via a second power electrode and a second ground electrode to provide a low beam;
An insulating tube having one end connected to the lead wire extended from the first and second ground electrodes of the first and second discharging means and the other end connected to an external ground power source;
A gas discharge headlamp for a vehicle, comprising: a glass enclosure connected to the base; and a base for disposing the lamp in an opening in the reflector. The first discharge means or the second discharge means is:
A pair of internal seals;
A discharge chamber having a hollow portion formed between the inner sealing portions and filled with a discharge gas;
A pair of discharge electrodes each end of which is installed in the discharge chamber at a predetermined interval;
A pair of metal foils installed in the internal sealing part and connected at one end to the other end of the discharge electrode;
A lead wire installed in the inner sealing portion, connected to the other end of the metal foil, and drawn out of the inner sealing portion;
A conductive sleeve that crimps and welds each of the lead wires drawn out from the internal sealing portion of the first discharge means and the internal sealing portion of the second discharge means toward the insulating tube;
2. The vehicle according to claim 1, further comprising a plurality of supports that support and fix the inner sealing portion of the first discharging means and the inner sealing portion of the second discharging means to the glass enclosure. Gas discharge headlamps.   3. The gas discharge headlamp for a vehicle according to claim 2, wherein the discharge chamber of the first discharge means and the discharge chamber of the second discharge means are located at different distances from the base.   2. The gas discharge headlamp for a vehicle according to claim 1, wherein the glass enclosure is filled with nitrogen for preventing arc generation at a low pressure.   The gas discharge headlamp for a vehicle according to claim 1, wherein the insulating tube is made of a ceramic material and disposed in the glass enclosure.   A power supply lead wire formed between the glass enclosure and the base, connecting the glass enclosure and the base, extending from the first discharge means and the second discharge means, and the insulating tube. 2. The gas discharge headlamp for a vehicle according to claim 1, further comprising a connection member made of an epoxy resin for insulating and fixing the ground lead wires extended in this manner.

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