JPH05131870A - Discharge lamp lighting device - Google Patents

Abstract

PURPOSE:To attain the common use of a control circuit for lighting high luminance discharge lamps so as to provide a low-priced discharge lamp lighting device. CONSTITUTION:High luminance discharge lamps 11, 12 are connected parallel to power supply lines. Trigger circuits 21, 22 are connected individually to the high luminance discharge lamps 11, 12, and lighting command signals 401, 402 are provided selectively at the switching time so as to be supplied to the high luminance discharge lamps 11, 12 with trigger pulse voltage Vt selected. At the switching time, a control circuit 4 temporarily stops the supply of lighting maintaining voltage Vd. to the power supply lines, and then supplies the lighting maintaining voltage Vd to the power supply lines 48, 49 so as to supply the selected high luminance discharge lamps 11, 12 with the lighting maintaining voltage Vd as well as the trigger pulse voltage Vt.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a discharge lamp lighting device using a high intensity discharge lamp.

[0002]

2. Description of the Related Art Conventionally, a headlamp lighting device for an automobile has been constructed by using a halogen lamp, but recently, although the electric power is about 2/3 of that of the halogen lamp, a luminous flux 3 to 4 times that of the halogen lamp is generated. High-intensity discharge lamps have been developed and are in the spotlight as headlights. A high-intensity discharge lamp is designed so that rare gas, mercury, and metal halides are sealed in a quartz glass tube, and the metal halides are vaporized by the heat generated by arc discharge so that the maximum amount of light is emitted. Is becoming A discharge lamp lighting device for lighting this high-intensity discharge lamp is disclosed in Japanese Patent Application No. 2-55893.

[0003]

By the way, a plurality of high-intensity discharge lamps are used, as in the case of constructing a headlight device capable of emitting a lobe beam and a high beam by using a high-intensity discharge lamp. In the case of individually driving the lamps, a circuit configuration in which the high-intensity discharge lamps are driven by independent drive systems is conceivable. However, in order to light a high-intensity discharge lamp, a complicated and expensive drive system including a trigger circuit that generates a high voltage when lighting, a control circuit that controls the trigger circuit or supplies a discharge sustaining voltage, and the like is required. For this reason, in a circuit configuration in which a plurality of high-intensity discharge lamps are driven by independent drive systems, as many expensive drive systems as the number of high-intensity discharge lamps are required, which is extremely expensive.

Therefore, an object of the present invention is to solve the above-mentioned problems, and when a plurality of high-intensity discharge lamps are turned on, the drive system of the control circuit for turning on the high-intensity discharge lamps is shared and the cost is low. A discharge lamp lighting device is provided.

Another object of the present invention is to provide a discharge lamp lighting device for a vehicle headlamp, which can switch between a low beam and a high beam.

[0006]

To solve the above-mentioned problems, the present invention is a discharge lamp lighting device having a high-intensity discharge lamp, a trigger circuit, and a control circuit, wherein the high-intensity discharge lamp comprises: At least two are provided, each connected in parallel to a power supply line, at least two trigger circuits are provided, each of which is individually connected to the high-intensity discharge lamp, and the high-intensity discharge lamp is provided. A lighting command signal is selectively given at the time of switching, the selected trigger circuit generates a high-voltage trigger pulse, and the trigger pulse is supplied to the selected high-intensity discharge lamp, The control circuit, during the switching, temporarily stops the supply of the lighting maintaining voltage to the power supply line,
After that, the lighting maintaining voltage is supplied to the power supply line, and the lighting maintaining voltage is supplied to the selected high-intensity discharge lamp together with the trigger pulse.

Further, the high-intensity discharge lamp includes a reflector, and the reflector has a concave light reflecting surface.
The reflector and the high-intensity discharge lamp, which are vertically arranged in front of the light reflecting surface, constitute a headlight for obtaining a lobe beam or a high beam.

[0008]

At least two trigger circuits are provided, each of which is individually connected to the high-intensity discharge lamp, and a lighting command signal is selectively given when the high-intensity discharge lamp is switched. Is generated and the trigger pulse is supplied to the selected high-intensity discharge lamp, the arc discharge of the selected high-intensity discharge lamp can be easily generated.

At least two high-intensity discharge lamps are provided, each of which is connected in parallel to the power supply line, and the control circuit temporarily supplies the lighting maintaining voltage to the power supply line at the time of switching. Since it is stopped, the high-intensity discharge lamp being turned on is surely turned off. After that, the lighting maintaining voltage is supplied to the power supply line, and the lighting maintaining voltage is supplied to the selected high-intensity discharge lamp together with the high-voltage trigger pulse, so that the selected high-intensity discharge lamp is lit. At this time, the high-intensity discharge lamps that are not selected are not supplied with the lighting sustain voltage, but are not lit because the high-voltage trigger pulse is not supplied. As a result, even when the high-intensity discharge lamps are connected in parallel, the high-intensity discharge lamps can be reliably switched without being affected by the magnitude of the arc discharge voltage of the high-intensity discharge lamps. Therefore, the drive system of the control circuit for lighting each high-intensity discharge lamp can be shared.

Further, including the reflector, the reflector has a concave light reflecting surface, the high-intensity discharge lamp is arranged vertically in front of the light-reflecting surface, and the reflector and the high-intensity discharge lamp are a lobby. Since the headlamp for obtaining a beam or a high beam is configured, a discharge lamp lighting device for a vehicle headlamp capable of switching between a low beam and a high beam can be obtained.

[0011]

1 is a block diagram showing the configuration of a discharge lamp lighting device according to the present invention. In the figure, 1 is a headlight, 1
1, 12 are high-intensity discharge lamps, 13 are reflectors, 21, 2
Reference numeral 2 is a trigger circuit, 4 is a control circuit, and 5 is a battery.

High intensity discharge lamp 11 and high intensity discharge lamp 12
Are connected in parallel to the power supply lines 48 and 49. In the high-intensity discharge lamp 11 and the high-intensity discharge lamp 12, rare gas, mercury, metal halide, etc. are sealed in the quartz glass tube, and the metal halide is vaporized by the heat generated by the arc discharge, and the maximum amount is obtained. It emits light.

The trigger circuit 21 is individually connected to the high-intensity discharge lamp 11, a lighting command signal 401 is selectively given when switching to the high-intensity discharge lamp 11, and a high-voltage trigger pulse voltage Vt is generated. The trigger pulse voltage Vt is supplied to the high-intensity discharge lamp 11. Therefore, the arc discharge of the high-intensity discharge lamp 11 can be easily generated. Similarly,
The trigger circuit 22 is individually connected to the high-intensity discharge lamp 12, and the lighting command signal 402 is input when switching to the high-intensity discharge lamp 12.
Is selectively applied to generate a high-voltage trigger pulse voltage Vt, and the trigger pulse voltage Vt is supplied to the high-intensity discharge lamp 12. Therefore, the high-intensity discharge lamp 12
Arc discharge can be easily generated.

The control circuit 4 supplies the power supply lines 48 and 4 when switching from the high-intensity discharge lamp 11 to the high-intensity discharge lamp 12 or when switching from the high-intensity discharge lamp 12 to the high-intensity discharge lamp 11.
The supply of the lighting maintaining voltage Vd to 9 is temporarily stopped,
After that, the lighting maintaining voltage Vd is applied to the power supply lines 48 and 49.
Is supplied to the selected high-intensity discharge lamp 11 or high-intensity discharge lamp 12 together with the trigger pulse voltage Vt and the lighting maintaining voltage Vt.
supply d. The temporary stop period of the supply of the lighting maintaining voltage Vd may be at least the time from the power interruption until the high-intensity discharge lamps 11 and 12 are extinguished. Further, the trigger pulse voltage Vt may be supplied to the high-intensity discharge lamps 11 and 12 when the supply of the lighting maintaining voltage Vd is restarted.
After 12 is turned on, it does not need to be constantly supplied.

As described above, the high-intensity discharge lamp 11 and the high-intensity discharge lamp 12 are connected in parallel to the power supply lines 48 and 49, and the control circuit 4 lights up the power supply lines 48 and 49 at the time of switching. Since the supply of the sustain voltage Vd is temporarily stopped, the high-intensity discharge lamp 11 or the high-intensity discharge lamp 12 that is being turned on is reliably turned off. The control circuit 4 then supplies the lighting maintaining voltage Vd to the power supply lines 48 and 49, and selects the high-intensity discharge lamp 11 or the high-intensity discharge lamp 1 selected.
Since the lighting sustaining voltage Vd is supplied to 2 together with the high-voltage trigger pulse voltage Vt, the selected high-intensity discharge lamp 11 or 12 is turned on. At this time, the high-intensity discharge lamp 11 or the high-intensity discharge lamp 12 that is not selected is not turned on because the lighting maintaining voltage Vd is supplied but the high-voltage trigger pulse voltage Vt is not supplied. Thus, even when the high-intensity discharge lamp 11 and the high-intensity discharge lamp 12 are connected in parallel, the high-intensity discharge lamp 11 and the high-intensity discharge lamp 12 are connected to each other.
The high-intensity discharge lamp 11 and the high-intensity discharge lamp 12 can be reliably switched regardless of the magnitude of the discharge voltage. Therefore, the drive system of the control circuit 4 for lighting the high-intensity discharge lamps 11 and 12 can be shared.

Further, in the embodiment, the control circuit 4 supplies the lighting command signal 402 to the trigger circuit 22 at the time of switching the lighting from the high-intensity discharge lamp 11 to the high-intensity discharge lamp 12, and the high-intensity discharge lamp 12 emits high brightness. A lighting command signal 401 is supplied to the trigger circuit 21 when the lighting of the discharge lamp 11 is switched. In this case, the control circuit 4 uses the power supply line 48,
Since it is possible to determine by itself the timing of the temporary stop of the supply of the lighting maintaining voltage Vd to 49 and the command timing of the lighting command signals 401 and 402, the supply of the lighting maintaining voltage Vd is temporarily stopped and the lighting maintaining voltage Vd is supplied. After restarting, the lighting command signals 401 and 402 can be commanded. Therefore, switching control of the high-intensity discharge lamps 11 and 12 can be surely performed.

In the embodiment, the high-intensity discharge lamp 11 and the trigger circuit 21 are connected in series, and the power supply line 48,
Since it is connected to 49, the lighting maintaining voltage Vd and the trigger pulse voltage Vt are superimposed and applied to the high-intensity discharge lamp 11, and the high-intensity discharge lamp 11 can be individually and most easily turned on. Similarly, since the high-intensity discharge lamp 12 and the trigger circuit 22 are connected in series and connected to the power supply lines 48 and 49, the high-intensity discharge lamp 12 is generated by superimposing the lighting sustaining voltage Vd and the trigger pulse voltage Vt. And the high-intensity discharge lamps 12 can be individually and most easily lit.

FIG. 2 is a block diagram showing the configuration of another embodiment of the discharge lamp lighting device according to the present invention. In the figure, the same reference numerals as those in FIG. 1 denote the same components.

In this embodiment, the lighting command signal 401 or the lighting command signal 402 is externally commanded. The lighting command signal 401 or the lighting command signal 402 is
It is supplied from the outside by an external changeover switch 3 and given to the trigger circuits 21 and 22 and the control circuit 4. The control circuit 4 temporarily stops the supply of the lighting maintaining voltage Vd when the lighting command signal 401 or the lighting command signal 402 is supplied. As a result, similarly to the embodiment of FIG. 1, it becomes possible to share the drive section of the control circuit 4 for lighting each high-intensity discharge lamp.

Further, in the embodiment, a reflector 13 is included,
The reflector 13 has a concave light-reflecting surface, the high-intensity discharge lamps 11 and 12 are vertically arranged in front of the light-reflecting surface, and the reflector 13 and the high-intensity discharge lamps 11 and 12 are lobe beams. Alternatively, since the headlamp 1 for obtaining a high beam is configured, a discharge lamp lighting device for a vehicle headlamp capable of switching between a low beam and a high beam can be obtained.

FIG. 3 is a specific circuit diagram of the discharge lamp lighting device according to the present invention. In the figure, the same reference numerals as those in FIG. 1 denote the same components.

The trigger circuit 21 is a high voltage transformer 211.
And a lighting pulse generation circuit 212. The output side winding of the high voltage transformer 211 and the high-intensity discharge lamp 11 are connected in series, and both ends of the series connection are the power supply line 48,
It is connected to 49. The input side winding of the high voltage transformer 211 is connected to the lighting pulse generation circuit 212. When switching to the high-intensity discharge lamp 11, the trigger circuit 21 receives the lighting command signal 401 from the control circuit 4, supplies a pulse from the lighting pulse generation circuit 212 to the high-voltage transformer 211, and the high-intensity discharge lamp 11 receives 10 to 15 kV. The trigger pulse voltage Vt is supplied to the lighting sustaining voltage Vd in a superimposed manner. Similarly, the trigger circuit 22 has a high voltage transformer 221 and a lighting pulse generation circuit 222.
The output winding of the high-voltage transformer 221 and the high-intensity discharge lamp 12 are connected in series, and both ends of the series connection are connected to power supply lines 48 and 49. The input side winding of the high voltage transformer 221 is connected to the lighting pulse generation circuit 222. When switching to the high-intensity discharge lamp 12, the trigger circuit 22 receives the lighting command signal 402 from the control circuit 4, supplies a pulse from the lighting pulse generation circuit 222 to the high-voltage transformer 221, and supplies the high-intensity discharge lamp 11 with 10 to 15 kV. The trigger pulse voltage Vt is supplied to the lighting sustaining voltage Vd in a superimposed manner.

The control circuit 4 includes a control signal generation circuit 40 and
Transformer 41, output circuit 42, and switching element 4
4, a current detection circuit 45, a pulse width control circuit 46,
It has switch elements 471 to 474.

The control signal generation circuit 40 inputs the switching signal, and when switching from the high-intensity discharge lamp 11 to the high-intensity discharge lamp 12, the control signal 403 for turning off the switch elements 471 and 472 is applied to the switch elements 471 and 472. Then, the lighting sustaining voltage Vd to the power supply lines 48 and 49 is stopped. After that, the control signal 404 for turning on the switch elements 473 and 474 is transmitted to the switch elements 473 and 474.
Power supply line 48, 49 to the lighting sustaining voltage V
supply d. The control signal generation circuit 40 then supplies the lighting command signal 402 to the trigger circuit 22. Similarly,
The control signal generation circuit 40 switches the switch elements 473 and 474 when switching from the high-intensity discharge lamp 12 to the high-intensity discharge lamp 11.
Control signal 404 for turning off the switch element 473, 4
74, and the supply of the lighting maintaining voltage Vd to the power supply lines 48 and 49 is stopped. After that, the control signal 403 for turning on the switch elements 471 and 472 is supplied to the switch elements 471 and 472, and the power supply line 48,
The lighting sustaining voltage Vd is supplied to 49. The control signal generation circuit 40 then causes the trigger circuit 21 to turn on the lighting command signal 401.
To supply.

The transformer 41 has an input winding 411 and an output winding 412. The input winding 411 is connected to the switching element 44 in series. Output winding 412
Are connected to the output circuit 42. Switching element 4
4 turns on, input winding 411 and output winding 412
An induced voltage having a black circle as a positive polarity is generated at the input terminal, and energy is transmitted from the input winding 411 to the output winding 412. When the switching element 44 is turned off and the input current is cut off, the excitation energy accumulated in the input winding 411 is transmitted to the output winding 412.

The output circuit 42 has a rectifying element 421 and a smoothing capacitor 422. The rectifying element 421 is
Energy transmission to the high-intensity discharge lamps 11 and 12 performed when the switching element 44 is turned on is blocked, and the excitation energy accumulated in the input winding 411 when the switching element 44 is turned off is supplied to the high-intensity discharge lamps 11 and 12. introduce. Specifically, the switching voltage boosted by the output winding 412 is obtained based on the excitation energy, the switching voltage is smoothed by the smoothing capacitor 422, and the lighting maintaining voltage Vd is supplied to the power supply lines 48 and 49. It

The switching element 44 turns on / off the DC input 5 by the switching signal 461 of the constant frequency f supplied from the pulse width control circuit 46, and the transformer 41.
To the input current Ii.

The input current detection circuit 45 detects the input current Ii and supplies the current detection signal 452 to the pulse width control circuit 46. Specifically, the resistor 451 is connected in series to the input winding 411, and the terminal voltage of the resistor 451 is supplied to the pulse width control circuit 46 as the current detection signal 452.

The pulse width control circuit 46 uses the current detection signal 4
Based on 52, the pulse width of the switching element 44 is controlled so that the input current Iip at the time of interruption has a constant value. Specifically, it has a pulse width modulation circuit 462, a reference voltage generation circuit 463 for generating a reference voltage Vref that is a set value, and a comparator 464. Comparator 464
Compares the reference voltage Vref with the current detection signal 452, and supplies the input current cutoff signal 465 to the pulse width modulation circuit 462 when the current detection signal 452 exceeds the reference voltage Vref. The pulse width modulation circuit 462 includes the switching element 4
4 is turned on at a constant frequency f, and the input current cutoff signal 465
Then, a switching signal 461 that turns off the switching element 44 is generated. Switching frequency f
Is usually set to about 20 kHz to 500 kHz.

The switch elements 471 to 474 form a full bridge with bipolar transistors or field effect transistors or the like in order to AC light the high-intensity discharge lamps 11 and 12 to extend their life. The switch elements 471 and 472 are turned on / off at the same time by the control signal 403 supplied from the control circuit 4, supply the lighting maintaining voltage Vd to the high-intensity discharge lamps 11 and 12, and give a current I1 in the forward direction.
Similarly, the switch elements 473 and 474 are turned on / off at the same time by the control signal 404 supplied from the control circuit 4, supply the lighting maintaining voltage Vd to the high-intensity discharge lamps 11 and 12, and give a current I2 in the negative direction. In this case, the switch elements 471 to 474 are driven at several hundreds to 10 kilohertz.

FIG. 4 is a time chart for explaining the operation of the pulse width control circuit. This will be described with reference to FIG.
The pulse width control circuit 46 supplies the switching signal 461 for turning on the switching element 44 to the switching element 44 at time t0. Along with this, a triangular wave current of Ii = (1 / L) ∫Vdt flows through the input winding 411. Here, L is the self-inductance of the input winding 411, and V is the voltage applied to the input winding 411. At time t1 when the current detection signal 452 exceeds the reference voltage Vref,
The comparator 464 supplies the input current cutoff signal 465 to the pulse width modulation circuit 462, and the input current Ii is cut off. As a result, a constant input current Iip is supplied to the input winding 411 when the input current Ii is cut off without being affected by the voltage fluctuation of the DC input 5. The value of the input current Iip can be easily changed by changing the reference voltage Vref.

As described above, the transformer 1 has the input winding 4
11 and the output winding 412, and the input winding 411 is connected in series to the switching element 44 and the input current detection circuit 45, the switching element 44 is turned on to input the input current Ii to the input winding 411. When supplied, energy is transferred from the input winding 411 to the output winding 412, and excitation energy according to the input current Ii is stored in the input winding 411. That is, assuming that the self-inductance of the input winding 411 is L and the input current is Iip, the exciting energy −W = L · I ² ip / 2 (J) is accumulated in the input winding 411.

The output circuit 42 blocks energy transmission when the rectifying element 421 turns on the switching element 44, and supplies the exciting energy accumulated in the transformer 41 to the high-intensity discharge lamps 11 and 12 when the switching element 44 is turned off. Therefore, only the exciting energy is supplied to the high-intensity discharge lamps 11 and 12. Further, the excitation energy is transmitted from the transformer 41 to the high-intensity discharge lamps 11 and 12 with substantially constant transmission efficiency.

Therefore, the power P supplied to the high-intensity discharge lamps 11 and 12 has a switching frequency of f, and the transfer efficiency from the input winding 411 to the high-intensity discharge lamps 11 and 12 is K.
Then, P = K · L · I ² ip · f / 2 (W). Therefore, the current value Iip when the input current Ii is cut off
Is set to a constant value, the high-intensity discharge lamps 11 and 12 can be driven at constant power.

The switching element 44 turns on / off the DC input by the switching signal 461 having a constant frequency supplied from the control circuit 46, and inputs the input current I to the input winding 411.
i, the input current detection circuit 45 detects the input current Ii, and supplies the current detection signal 452 to the control circuit 46. Based on the current detection signal 452, the control circuit 46 receives the input current Ii.
Since the pulse width of the switching element 44 is controlled so that ip becomes a constant value, regardless of the voltage fluctuation of the DC input 5,
The current value Iip when the input current Ii is cut off can be made constant for each cycle.

As a result, the same effect as in FIG. 1 can be obtained, the high-intensity discharge lamp can be driven with a constant power with a simple circuit configuration, and the reference voltage Vref can be set to a high beam or a low beam. It is possible to provide a discharge lamp lighting device that can easily change the light emission amount of the high-intensity discharge lamp by changing the light intensity according to the above.

[0037]

As described above, according to the present invention, the following effects can be obtained. (A) At least two trigger circuits are provided, each of which is individually connected to the high-intensity discharge lamp, and a lighting command signal is selectively given when the high-intensity discharge lamp is switched, and the selected trigger circuit has a high voltage. Since the trigger pulse is generated and supplied to the selected high-intensity discharge lamp, a discharge lamp lighting device capable of individually triggering each high-intensity discharge lamp to discharge easily is provided. it can. (B) At least two high-intensity discharge lamps are provided, each of which is connected in parallel to the power supply line, and the control circuit temporarily supplies the lighting maintaining voltage to the power supply line at the time of switching. After stopping, the lighting sustaining voltage is supplied to the power supply line, and the lighting sustaining voltage is supplied to the selected high-intensity discharge lamp together with the high-voltage trigger pulse, so that a plurality of high-intensity discharge lamps are connected in parallel to light. In this case, the drive system of the control circuit for lighting the high-intensity discharge lamp can be shared, and an inexpensive discharge lamp lighting device can be provided. (C) A reflector is included, and the reflector has a concave light-reflecting surface, the high-intensity discharge lamp is arranged vertically in front of the light-reflecting surface, and the reflector and the high-intensity discharge lamp are in the form of a rope or a beam. Since the headlight that obtains the high beam is configured, it is possible to provide a discharge lamp lighting device for a headlight of an automobile that can switch between a low beam and a high beam.

[Brief description of drawings]

FIG. 1 is a block diagram showing a configuration of a discharge lamp lighting device according to the present invention.

FIG. 2 is a block diagram showing the configuration of another embodiment of the discharge lamp lighting device according to the present invention.

FIG. 3 is a specific circuit diagram of the discharge lamp lighting device according to the present invention.

FIG. 4 is a time chart explaining the operation of the pulse width control circuit.

[Explanation of symbols]

 1 Headlight 11, 12 High-intensity discharge lamp 21, 22 Trigger circuit 4 Control circuit 48, 49 Power supply line 401, 402 Lighting command signal 403, 404 Control signal 5 Battery Vd Lighting maintenance voltage Vt Trigger pulse voltage

─────────────────────────────────────────────────── ─── Continuation of the front page (51) Int.Cl. ⁵ Identification number Office reference number FI technical display location H05B 41/24 K 7913-3K 41/29 C 7913-3K

Claims (5)

[Claims] 1. A discharge lamp lighting device having a high-intensity discharge lamp, a trigger circuit, and a control circuit, wherein at least two high-intensity discharge lamps are provided.
Each is connected in parallel to a power supply line, at least two trigger circuits are provided, each is individually connected to the high-intensity discharge lamp, and a lighting command signal is selected when switching the high-intensity discharge lamp. The selected trigger circuit generates a high-voltage trigger pulse,
The trigger pulse is supplied to the selected high-intensity discharge lamp, the control circuit temporarily stops the supply of the lighting maintaining voltage to the power supply line at the time of the switching, and then the power supply. A discharge lamp lighting device, characterized in that the lighting maintenance voltage is supplied to a supply line, and the lighting maintenance voltage is supplied to the selected high-intensity discharge lamp together with the trigger pulse. 2. The discharge lamp lighting device according to claim 1, wherein the control circuit supplies the lighting command signal to the trigger circuit during the switching. 3. The lighting command signal is externally supplied by an external changeover switch and given to the trigger circuit and the control circuit, and the control circuit lights the power supply line in response to the lighting command signal. The discharge lamp lighting device according to claim 1, wherein the supply of the sustain voltage is temporarily stopped. 4. The trigger circuit and the high-intensity discharge lamp are connected in series, and both ends of which are connected in series are connected to the power supply line. The discharge lamp lighting device according to. 5. A reflector is provided, wherein the reflector has a concave light-reflecting surface, and the high-intensity discharge lamp is arranged in a vertical direction in front of the light-reflecting surface. The discharge lamp lighting device according to claim 1, 2, 3 or 4, wherein the brightness discharge lamp constitutes a headlamp for obtaining a lobe beam or a high beam.