JP2011009060A - Discharge lamp device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a discharge lamp device capable of restricting malfunction in distribution of luminous intensity due to vibration.SOLUTION: This discharge lamp device includes: a burner BN; and a circuit portion CR holding the burner BN on a front end side thereof. The discharge lamp device is lighted in the condition wherein the tube axis is maintained nearly horizontal. The circuit portion CR includes: a case 3; a transformer 61; a first circuit element group 62 for generating high-voltage pulses with the transformer 61; a second circuit element group 63 for supplying rated power to the burner BN; and a connector 8 arranged to be projected from the case 3. The transformer 61 is arranged on a front end side inside of the case 3.

Description

  The present invention relates to a discharge lamp device used for automobile headlamps and the like.

  High-intensity discharge lamps, so-called HID lamps, are widely used as light sources used for automobile headlamps. To turn on this discharge lamp, an igniter that is a circuit device that generates and applies a high voltage to the lamp to start the lamp, and a circuit device that supplies the rated power to the lamp after starting and maintains the lighting of the lamp. Some ballast is needed. In Japan, a lamp, an igniter, and a ballast are generally configured separately, but in Europe and the United States, as in Patent Document 1 and Patent Document 2, a lamp and an igniter are generally configured integrally. Is.

  In recent years, as in Patent Document 3, a new circuit device has been developed in which a ballast and an igniter, which are circuit devices for maintaining the lighting of the lamp, are integrally formed.

JP 2008-159509 A International Publication No. 2005/008125 pamphlet JP 2008-305641 A

  However, in the discharge lamp device including the newly developed circuit device, there is a problem of poor light distribution. As a result of investigating this problem, the weight of the circuit device has increased, and the weight balance of the discharge lamp device has deteriorated, and the position of the arc formed between the electrodes during lighting is likely to change due to vibration and the like. Was found to be the cause. In particular, a discharge lamp that does not enclose mercury is greatly affected by a change in the position of the arc because the arc is thin.

  An object of the present invention is to provide a discharge lamp device capable of suppressing light distribution failure due to vibration or the like.

  In order to achieve the above object, a discharge lamp device according to the present invention comprises a burner and a circuit unit for holding the burner on its front end side, and is a discharge lamp device that is lit in a state where the tube axis is substantially horizontal. The circuit unit includes a case, a transformer, a first circuit element group that generates a high-voltage pulse by the transformer and starts the burner, and a second circuit element that supplies rated power to the burner. And a connector disposed so as to protrude from the case, and the transformer is disposed on a front end side in the case.

  According to the present invention, it is possible to suppress poor light distribution due to vibration or the like.

The figure for demonstrating the discharge lamp apparatus of the 1st Embodiment of this invention. Sectional drawing for demonstrating the discharge lamp apparatus of FIG. The figure for demonstrating the circuit structure of the discharge lamp apparatus of this Embodiment. The figure for demonstrating the discharge lamp apparatus of the 2nd Embodiment of this invention. The figure for demonstrating the motor vehicle headlamp of the 3rd Embodiment of this invention.

(First embodiment)
A discharge lamp device according to an embodiment of the present invention will be described with reference to the drawings. FIG. 1 is a diagram of a discharge lamp device according to a first embodiment of the present invention, and FIG. 2 is a sectional view of the discharge lamp device of FIG. In the following, for convenience, the left side (front end side of the discharge lamp device) in FIG. 1 will be referred to as the front end, and the right side will be referred to as the rear end.

  As shown in FIG. 1, the discharge lamp device according to the present embodiment includes a burner BN and a circuit unit CR.

The burner BN is a part that generates light, and includes the inner tube 1 as a main part. The inner tube 1 includes a light emitting unit 11 and a sealing unit 12. The light emitting part 11 is substantially elliptical and is located at the approximate center in the longitudinal direction of the inner tube 1. Inside the light-emitting unit 11, the volume is formed a discharge space 111 of 20mm ³ ~30mm ^3. As the inner tube 1, it is desirable to use quartz glass excellent in heat resistance and translucency.

  The discharge space 111 is filled with sodium, scandium, zinc, and indium halide and 12 to 20 atm of xenon at room temperature (25 ° C.). Note that mercury is not substantially enclosed in the discharge space 111. This “substantially free of mercury” means that the amount of mercury enclosed is optimally 0 mg, but it is almost equal to that of a conventional mercury-containing discharge lamp. This means that an amount of mercury, for example, less than 2 mg per ml, preferably 1 mg or less, is allowed to be contained.

  The sealing part 12 is plate-shaped, and a pair is formed at both ends of the light emitting part 11, and the mount 2 is sealed inside. The mount 2 includes a metal foil 21, an electrode 22, a coil 23, and a lead 24.

  The metal foil 21 is made of molybdenum and is sealed so that its plane is parallel to the plate-like surface of the sealing portion 12.

  One end of the electrode 22 is connected to the metal foil 21, and the other end is disposed in the discharge space 111 such that the front end faces each other while maintaining an inter-electrode distance of 4.0 mm to 4.5 mm in appearance distance. ing. In this embodiment, a so-called tritan electrode in which a small amount of thorium oxide is doped in tungsten is used.

  The coil 23 is made of doped tungsten, and is spirally wound around the shaft portion of the electrode 22 in the sealing portion 12.

  The lead 24 is made of molybdenum. One end of the lead 24 is connected to the metal foil 21 on the opposite side of the electrode 22, and the other end extends to the outside of the inner tube 1 along the tube axis. Among these, the support wire 25 is connected to the lead 24 extending to the lamp front end side. The support wire 25 is an L-shaped metal wire made of nickel, and a sleeve 26 made of ceramic is attached to a portion parallel to the burner BN.

  A cylindrical outer tube 13 is provided concentrically with the inner tube 1 on the outer side of the inner tube 1 configured as described above. The inner and outer pipes are connected by welding both ends of the inner pipe 1 and the outer pipe 13 together. A space formed between the inner tube 1 and the outer tube 13 is filled with nitrogen gas having a pressure of about 0.1 atm. The outer tube 13 is preferably made of a material having a thermal expansion coefficient close to that of the inner tube 1 and having an ultraviolet blocking property. For example, quartz glass to which an oxide such as titanium, cerium, or aluminum is added is used. be able to.

  The circuit unit CR is a device for starting and stably lighting the burner BN, and includes a case 3 made of PPS resin as an envelope. The case 3 includes a main body 31 and a lid 32 that can be fitted together.

  The main body part 31 has a base part 311 on the front end side, and the base part 311 holds a burner BN. The metal band 41 is attached to the outer peripheral surface of the outer tube 13, and the metal band 41 is clamped by a metal tongue piece 42 that protrudes from the base portion 311.

  In addition, a space is formed in the main body 31. This space is divided into an upper space 51 and a lower space 52 by a space dividing wall 312 formed inside the main body 31 along the tube axis direction.

A transformer 61 is disposed on the front end side of the upper space 51 of the case 3. The transformer 61 is formed by winding a primary winding and a secondary winding on an elongated rod-shaped iron core, and is housed in a container filled with an insulating material such as epoxy in order to ensure insulation. Used in. The transformer 61 is connected to a high voltage terminal 33, and the high voltage terminal 33 is connected to the lead 24 led out to the internal space of the main body 31. Since this connecting portion is a portion to which a high voltage pulse is applied at the time of starting, it is desirable to pot an insulating material as shown in FIG. 2 or newly provide a resin wall or the like in order to ensure insulation.
Further, a first circuit element group 62 that generates a high-pressure pulse by the transformer 61 and starts the burner BN is disposed on the rear end side of the upper space 51. The first circuit element group 62 is composed of capacitors, gaps, resistors, and the like, which are implanted on a mounting substrate 71 having a built-in wiring. Note that “arranged on the front end side (rear end side) of the case 3” means that when the length in the tube axis direction of the case is L, most of it is on the front end side (rear end side) than L / 2, for example, It means a state where 80% or more are arranged.

On the front end side of the lower space 52 of the case 3, the connector 8 is arranged so that a part thereof protrudes from the case 3. The connector 8 is connected to the support wire 25 led out to the internal space of the main body 31.
A second circuit element group 63 for supplying rated power to the burner BN is disposed on the rear end side of the lower space 52. The second circuit element group 62 includes capacitors, resistors, switching elements, diodes, microcomputers, and the like, and these are implanted on a mounting substrate 72 that contains wiring therein. In the second circuit element group 62, the capacitor is particularly arranged on the rear end side of the lower space 52.

  Around the case 3 provided with these circuit elements and the like, a shield case 9 for blocking electromagnetic noise is provided. The shield case 9 is composed of a case 91 and a case 92, which are fitted together and integrated. As the shield case 9, for example, aluminum can be used.

  The circuit configuration of the discharge lamp device of the present embodiment is as shown in FIG. The discharge lamp device includes a connector CR, a circuit unit CR including a second circuit element group 63 and a first circuit element group 62, and a burner BN. The connector 8 portion is connected to a battery or the like via a switch SW. Connected to the DC power source DS.

  The second circuit element group 63 includes a DC / DC converter circuit 631, a voltage detection circuit 632, a current detection circuit 633, a DC / AC inverter circuit 634, and a control circuit 635. The DC / DC converter circuit 631 is a boost chopper circuit that boosts and outputs a DC voltage of the DC power supply DS. The DC / DC converter circuit 631 is provided with a step-up transformer. The step-up transformer also serves as a transformer 61 that generates a high-voltage pulse for starting the burner BN together with the first circuit element group 62. Yes. The voltage detection circuit 632 and the current detection circuit 633 are circuits that detect the output voltage and output current of the DC / DC converter circuit 631, respectively. The DC / AC inverter circuit 634 is a bridge circuit that converts direct current into alternating current and outputs the alternating current. The control circuit 635 uses the DC / DC converter circuit 631 and the DC / DC converter circuit 631 and the DC / DC converter circuit 631 so that predetermined rated power is input to the burner BN based on the voltage value and current value detection results of the voltage detection circuit 632 and the current detection circuit 633. This is a circuit for controlling the AC inverter circuit 634.

  The first circuit element group 62 is a circuit that generates a high-pressure pulse necessary for starting the lamp and starts the burner BN by the transformer 61 configured as a part of the step-up transformer described above.

  With such a circuit configuration, the circuit unit CR generates a high voltage pulse of about 20 kV for starting the burner BN, and immediately after starting 65 W to 75 W, which is more than twice the stable power, and 25 to 25 when stable. 35 W electric power is generated and supplied to the burner BN.

  Here, the discharge lamp device of the present embodiment was attached to a reflector (refer to the third embodiment and FIG. 5 for details of the mounting structure), and a test was performed to light the entire device while vibrating. As a result, it was confirmed that even if the entire apparatus was vibrated, there was little variation in the position of the discharge arc formed between the pair of electrodes 22 during lighting, and there was no light distribution failure. This is because the weight balance in the tube axis direction of the discharge lamp device is improved by arranging a relatively heavy transformer 61 on the front end side and the upper space 51 side of the case 3 in the base portion 311 serving as a fulcrum. is there. In this way, the effect that the position variation of the discharge arc is reduced even if it vibrates is very meaningful in a discharge lamp that does not enclose mercury, because the arc becomes thinner, and the light distribution easily changes even with slight variations in the discharge arc. It can be said that it is big. In addition, in order to further improve the weight balance and reduce the upper and lower weight deviation of the discharge lamp device, the fact that the connector 8 to which the harness is attached is arranged on the front end side and the lower space 52 side has also led to suppression of poor light distribution. Conceivable.

  Further, in the discharge lamp device according to the present embodiment, the first circuit element group 62 and the second circuit element group 63 are arranged on the rear end side of the case 3 that is long in the tube axis direction, so the life of the circuit elements is extended. The effect is obtained. This is because the distance between these circuit elements and the light emitting section 11 and the transformer 61 is maintained, heat at the time of lighting is hardly transmitted, and the temperature rise of the circuit elements can be suppressed. When the mounting substrate 72 is arranged along the tube axis direction as in the present embodiment, the capacitor of the first circuit element group 62 that is large in size and weak against heat is connected to the case 3 particularly on the rear end side. It is optimal to arrange it (for example, on the rear end side with respect to L / 4). Here, since the first circuit element group 62 and the second circuit element group 63 are relatively light in weight, even if they are arranged on the rear end side of the case 3, the weight balance is not greatly deteriorated.

  Therefore, in the present embodiment, the circuit unit CR includes the case 3, the transformer 61, the transformer 61, the first circuit element group 62 that starts the burner BN by generating a high-voltage pulse, and the rated power to the burner BN. The second circuit element group 63 for supplying the power and the connector 8 arranged so as to protrude from the case 3, and the transformer 61 is arranged on the front end side in the case 3. Therefore, even if vibration is applied to the discharge lamp device, the position variation of the discharge arc formed between the pair of electrodes 22 during lighting can be suppressed, and poor light distribution can be suppressed.

  In addition, a space dividing wall 312 that divides the internal space into an upper space 51 and a lower space 52 is formed in the case 3, the transformer 61 is on the front end side and the upper space 51 side in the case 3, and the connector 8 is in the case 3. Since the weight balance in the tube axis direction is improved and the weight deviation in the vertical direction can be reduced, the light distribution failure can be further suppressed.

  In addition, since the first circuit element group 62 and the second circuit element group 63 are arranged on the rear end side in the case 3, the distance between the heat source and those circuit elements can be maintained, so that the service life is extended. can do.

  Further, since the capacitors included in the second circuit element group 63 are arranged on the rear end side in the case 3 and on the lower space 52 side, the distance from the light emitting unit 11 and the transformer 61 is increased. Can be prevented.

(Second Embodiment)
FIG. 4 is a cross-sectional view of a discharge lamp device according to the second embodiment of the present invention. About each part of embodiment after this, the same part as each part of the discharge lamp apparatus of 1st Embodiment is shown with the same code | symbol, and the description is abbreviate | omitted.

  In the second embodiment, the space dividing wall 312 is approximately half in the longitudinal direction of the case 3, and the circuit elements are configured by the first circuit element group and the second circuit element group on the rear end side of the case 3. The mounting substrate 7 on which the group 64 is mounted is disposed substantially perpendicular to the tube axis. With this structure, the wiring arrangement is simplified as compared with the first embodiment, so that the circuit element group 64 can be easily incorporated into the case 3. When the mounting substrate 7 is arranged perpendicular to the tube axis as in the present embodiment, the capacitor is placed on the rear end side of the case 3 and on the lower space 52 side in order to reduce the influence of heat. It is best to place it. In the present embodiment, a part of each circuit element may be shared by the igniter and the ballast to reduce the number of circuit elements.

(Third embodiment)
FIG. 8 is a diagram for explaining an automobile headlamp according to a third embodiment of the present invention.

  The automobile headlamp includes a discharge lamp device 101, a reflector 102, a light shielding control plate 103, a lens 104, and a harness 105.

  The discharge lamp device 101 is the lamp described in detail in the first embodiment.

  The reflector 102 is a parabolic metal member provided to reflect the light generated by the discharge lamp device 101 to the front side. An opening is formed in the vicinity of the center, and the base 311 portion of the discharge lamp device 101 is fixed to the opening end so that the burner BN is positioned inside the reflector 102.

  The light shielding control plate 103 is a metal member provided in order to form a light distribution called a cut line. The light shielding control plate 103 is movable, and can be switched from a low beam to a high beam by tilting forward on the bottom side.

  The lens 104 is a convex lens provided to collect the light reflected by the reflector 102 to form a desired light distribution, and is arranged at the opening on the tip side of the reflector 102.

  The harness 105 is a conducting wire that connects the discharge lamp device 101 and an external power source. A terminal is formed at one end and is connected to the connector 8 by fitting. Depending on the specifications, the harness 105 may wrap a metal wire around the conducting wire in order to remove electromagnetic noise generated in the discharge lamp device 101 or the like. In this case, the harness 105 is a relatively heavy conducting wire. Become.

  In such an automobile headlamp, since the base part 311 is attached to the reflector 102, if the weight of the circuit part CR is heavy, it is easily affected by vibration. That is, there is a possibility that the position of the burner BN fluctuates with the base 311 as a fulcrum due to vibration, the position of the arc formed between the electrodes moves during lighting, and the light distribution changes. In the present invention, since a transformer and a connector are arranged on the front end side of the circuit unit CR, the influence of vibration is reduced, so that light distribution failure can be suppressed.

  The embodiment of the present invention is not limited to the above, and may be modified as follows, for example.

  The space dividing wall 312 is not limited to being formed integrally with the main body 31 of the case 3, but may be formed by fitting a separately formed wall into the main body 31 later, or the transformer 61. The container itself that accommodates the container may be configured as a wall.

  The transformer 61 is not limited to a rod shape, and may be a box shape or a donut shape. Further, when the internal structure of the case 3 is changed so that the insulation between the transformer and other circuit elements can be sufficiently maintained, the transformer 61 does not need to be accommodated in the case filled with the insulating material. Further, the number of transformers 61 is not limited to one, and a plurality of transformers 61 may be provided. In this case, a transformer that generates a high-pressure pulse for starting the burner BN may be disposed at least on the front end side of the case 3.

  The connector 8 does not need to be configured as a separate member, and may be configured integrally with the case 3. In particular, in the first embodiment, the connector 8 may be formed on the mounting board 72 or a part thereof.

BN burner CR circuit part 1 inner pipe 13 outer pipe 2 mount 3 case 311 base part 312 space dividing wall 51 upper space 52 lower space 61 transformer 62 first circuit element group 63 second circuit element 8 connector

Claims (4)

A discharge lamp device comprising a burner and a circuit unit for holding the burner on the front end side thereof, wherein the tube axis is lit in a substantially horizontal state,
The circuit unit includes a case, a transformer, a first circuit element group that generates a high-voltage pulse by the transformer, and starts the burner; a second circuit element group that supplies rated power to the burner; And a connector arranged to protrude from the case,
The discharge lamp device according to claim 1, wherein the transformer is disposed on a front end side in the case.   The case includes a space dividing wall that divides at least a part of an internal space into an upper space and a lower space, the transformer is on the front end side and the upper space side in the case, and the connector is in the case. The discharge lamp device according to claim 1, wherein the discharge lamp device is disposed on a front end side of the lamp and on the lower space side.   The discharge lamp device according to claim 1 or 2, wherein the first circuit element group and the second circuit element group are arranged on a rear end side in the case.   The first circuit element group or the second circuit element group includes a capacitor, and the capacitor is disposed on the rear end side and the lower space side in the case. The discharge lamp device according to claim 2 or claim 3.

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