JPH07142182A - Discharge lamp lighting circuit for vehicle - Google Patents

Abstract

PURPOSE:To simplify the structure of a start pulse generating circuit, shorten the delay time in generating the start pulse, and increase the certainty of lighting. CONSTITUTION:A lighting circuit 1 boosts the DC input voltage with a DC boosting circuit 6, converts it into the rectangular wave voltage with a DC/AC converting circuit 16, superimposes the start pulse from a start pulse generating circuit 22 on it, and feeds the voltage to a discharge lamp 21. The secondary side of the transformer 7 of the DC boosting circuit 6 is provided with a start winding 7c separately from a feed winding 7b to the discharge lamp 21 and a rectifying circuit 11 of the next stage. A capacitor 25 is charged via a resistor 27 and a diode 28 only during the period that the rectangular wave voltage V2 outputted from the DC/AC converting circuit 16 is kept at a high level when the terminal voltage becomes a prescribed value or above. A correlation is provided between the direction of the generated voltage by the start pulse and the polarity of the rectangular wave.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a novel lighting circuit for a vehicle discharge lamp. Specifically, the structure of the starting pulse generation circuit for generating and applying the starting pulse to the discharge lamp at the initial stage of lighting the discharge lamp is simplified, and the delay time related to the generation of the starting pulse is shortened and The present invention provides a novel lighting circuit for a vehicle discharge lamp capable of increasing the certainty.

[0002]

2. Description of the Related Art Regarding the lighting of a high pressure discharge lamp such as a metal halide lamp, it is necessary to generate a starting pulse for supplying the starting pulse to the discharge lamp.

FIG. 3 shows an example of the configuration of a conventional lighting circuit.

The lighting circuit a has a direct current boosting circuit b, a bridge circuit c, and a starting pulse generating circuit d, and a direct current input voltage is boosted by the direct current boosting circuit b, and then a rectangular wave voltage is applied by the latter bridge circuit c. It is supplied to the discharge lamp after being converted into the discharge lamp, and is configured so that the discharge lamp is started by the starting pulse generating circuit d provided in the subsequent stage of the bridge circuit c.

The DC boosting circuit b has, for example, a flyback type DC-DC converter configuration, and includes a transformer e and
A semiconductor switch element f (indicated by a switch symbol in the figure) that is connected in series to the primary winding and is switching-controlled by a control unit (not shown), and a rectifier circuit g provided on the secondary winding side of the transformer e. It consists of and.

Further, the bridge circuit c is constructed so that an alternating output can be obtained by alternately switching two pairs of semiconductor switching elements.

The starting pulse generating circuit d has a voltage doubler rectifying circuit h, a transformer i, a bidirectional self-breakdown type switching element j (indicated by a switch symbol in the figure), and a capacitor k. When the terminal voltage of the capacitor k reaches a predetermined level by the output of the voltage rectifier circuit h, the self-breakdown type switch element j breaks down, and the pulse generated at this time is boosted by the transformer and is the output of the bridge circuit c. It is adapted to be superimposed on the wave and applied to the discharge lamp l. As a result, the DC boost circuit b and the bridge circuit c
The withstand voltage of the component can be set to a low value.

[0008]

However, in the above-mentioned conventional lighting circuit a, the number of parts constituting the voltage doubler rectifying circuit h is considerably large, and it takes time to generate the starting pulse. There is a problem such as being overloaded.

Therefore, as shown in the lighting circuit m of FIG.
In the starting pulse generating circuit d, a winding n is added to the secondary side of the transformer forming the DC boosting circuit b and a rectifying circuit o is provided to obtain a high voltage output equivalent to the output voltage of the voltage doubler rectifying circuit h. It is conceivable to charge the capacitor k of No. 1 and generate a pulse in the primary winding of the transformer i by the breakdown of the self-breakdown type switch element j. As a result, only the winding n and the rectifier circuit o having a simple structure need be provided to charge the capacitor k, and the constituent elements that delay the generation of the starting pulse can be eliminated as much as possible.

By the way, in the lighting circuit m, the voltage direction of the starting pulse occurs regardless of the polarity of the rectangular wave output from the bridge circuit c. The problem remains that there is variation in the ease of transition to. For that purpose, it is possible to use a switch element having a trigger terminal instead of the self-breakdown type switch element j to generate a starting pulse in accordance with a specific polarity of a rectangular wave. A drive circuit for the switch element is required, which goes against the desired simplification of the circuit configuration.

[0011]

In order to solve the above-mentioned problems, a lighting circuit for a vehicle discharge lamp according to the present invention is provided with a DC boosting circuit for boosting a DC input voltage using a transformer, and the DC boosting circuit. A DC-AC conversion means for converting the output voltage of the circuit into an AC voltage and supplying it to the discharge lamp, and a starting pulse for the discharge lamp are generated and superposed on the output of the DC-AC conversion means and then discharged. A lighting circuit for a vehicle discharge lamp including a starting pulse generating circuit for supplying to an electric lamp has the following configurations (a) to (d).

That is, (b) 2 of the transformer of the DC boost circuit
On the next side, a starting winding different from the winding for supplying power to the discharge lamp is provided, and a rectifying circuit for rectifying the output voltage of the starting winding is provided.

(B) The secondary winding of the transformer constituting the starting pulse generating circuit is provided on the first power supply line connecting the output terminal of the DC / AC converting circuit and the discharge lamp, and
A capacitor and a self-breakdown switch element are connected in series to the next winding so that a series circuit of the element, the primary winding, and the capacitor is closed when the self-breakdown switch element breaks down. ) The positive output terminal of the rectifier circuit is connected between the self-breakdown switch element and the capacitor via a resistor and a diode connected in the forward direction, and the other output terminal of the rectifier circuit is connected to the DC-AC converter circuit. Is connected to a second power supply line that connects the output terminal and the discharge lamp.

(D) The breakdown point of the self-breakdown type switching element is in a range not less than the difference voltage between the output voltage of the rectifier circuit and the output voltage of the DC-AC conversion circuit and not more than the sum voltage of the two. Set to.

[0015]

According to the present invention, the capacitor of the starting pulse generating circuit is charged by the output of the starting winding and the rectifying circuit provided on the secondary side of the DC boosting circuit, and the terminal voltage of the capacitor reaches a predetermined value. At this time, the pulse generated in the primary winding of the transformer of the starting pulse generating circuit is superimposed on the output of the DC-AC converting circuit and supplied to the discharge lamp to simplify the configuration of the starting pulse generating circuit. Therefore, it is possible to eliminate the component that causes the delay of the generation of the starting pulse.

When the voltage difference between the voltage of the first power supply line and the positive side output of the rectifier circuit exceeds a predetermined level, the charging period of the capacitor is limited, and the capacitor is started only during the charging period. So that a discharge pulse is generated, the transition from glow discharge to arc discharge of the discharge lamp can be facilitated by establishing a relationship between the starting pulse generation time and the specific phase of the DC-AC conversion circuit output voltage. You can guarantee stable lighting.

[0017]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS The details of the lighting circuit of the vehicle discharge lamp of the present invention will be described below with reference to the illustrated embodiments. In the illustrated embodiment, the present invention is applied to a lighting circuit of an automobile metal halide lamp.

FIG. 1 shows the structure of the lighting circuit 1, in which a battery 2 is connected between the DC voltage input terminals 3 and 3 '.

Reference numerals 4 and 4'represent DC power supply lines, and a lighting switch 5 is provided on one of the plus lines 4.

Reference numeral 6 denotes a DC boosting circuit provided for boosting the battery voltage, which is a flyback type DC-DC.
A converter configuration is used, and includes a transformer 7 and a semiconductor switch element 8 (indicated by a switch symbol in the drawing).

As shown in the figure, the semiconductor switch element 8 is connected in series to the primary winding 7a of the transformer 7 and is designed to be switching-controlled by a control circuit (not shown). The capacitor 9 is connected in parallel.

Two windings 7b and 7c are provided on the secondary side of the transformer 7, and the winding 7 serving as a power feeding winding is provided.
The output of b is sent to the DC-AC conversion circuit in the subsequent stage through the rectifying circuit 10, and the output of the winding 7c which is the starting winding is sent to the starting pulse generating circuit in the subsequent stage via the rectifying circuit 11. ing. The windings 7b and 7c are wound in reverse phase with respect to the primary winding 7a.

The rectifier circuit 10 comprises a diode 12 and a capacitor 13, the anode of the diode 12 is connected to one end of the winding 7b, and the cathode of the diode 12 is connected via the capacitor 13 to the other end of the winding 7b. It is connected.

The rectifier circuit 11 is also composed of a diode 14 and a capacitor 15, the anode of the diode 14 is connected to one end of the winding 7c, and the cathode of the diode 14 is connected via the capacitor 15 to the winding 7c. Connected to the end.

Reference numeral 16 is a DC-AC conversion circuit, which is provided in the subsequent stage of the DC boosting circuit 6 and converts the DC voltage sent from the DC boosting circuit 6 into a rectangular wave voltage. The DC-AC conversion circuit 16 includes a semiconductor switch element 17 indicated by a switch symbol as shown in the figure.
(I) A bridge circuit 18 composed of (i = 1, 2, 3, 4) and its drive control circuit 19.
These semiconductor switch elements are paired with the semiconductor switch elements 17 (1) and 17 (4) and the semiconductor switch elements 17 (2) and 17 (3), respectively, and are sent from the drive control circuit 19 as control signals. Thus, reciprocal switching control is performed.

The rectangular wave output from the DC / AC conversion circuit 16 is supplied to the power supply lines 20 (2) and 17 (1) from between the semiconductor switch elements 17 (3) and 17 (4).
And power supply line 20 drawn from between 17 (2)
It is supplied to the metal halide lamp 21 via (1).

Reference numeral 22 is a starting pulse generating circuit, which is arranged at the subsequent stage of the DC-AC converting circuit 16 so that the starting pulse is generated with a certain relation to the voltage phase of the power feeding line 20 (2). Is configured.

Reference numeral 23 is a transformer, and its primary winding 23
The a and the secondary winding 23b are antiphase wound. The secondary winding 23b is provided on the power supply line 20 (1), and one end of the primary winding 23a is connected to the terminal of the secondary winding 23b on the side opposite to the metal halide lamp 21 side. , A self-breakdown type switch element 24 (indicated by a switch symbol in the figure) is connected to one end of the primary winding 23a, and the other end of the primary winding 23a is self-breakdown via a capacitor 25 and a resistor 26 connected in parallel with each other. Type switching element 24
Is connected to the other terminal.

The capacitor 25 is adapted to be charged from the winding 7c and the rectifying circuit 11 through a resistor 29, a diode 28 and a line 29 extending to the capacitor 25. That is, the cathode of the diode 14 of the rectifier circuit 11 is connected to the anode of the diode 28 via the resistor 27, and the cathode of the diode 28 is connected between the self-breakdown switch element 24 and the capacitor 25.

The terminal on the side opposite to the diode 14 among the terminals of the capacitor 15 of the rectifying circuit 11 is the power supply line 20.
It is connected to (2).

In the starting pulse generating circuit 22, when the terminal voltage of the capacitor 25 charged by the output of the rectifying circuit 11 reaches a predetermined value, the self-breakdown type switching element 24.
The pulse generated by the breakdown of the voltage is boosted by the transformer 23 and superposed on the rectangular wave of the bridge circuit 18, but this starting pulse is the power supply line 20 (2).
This occurs only when the voltage phase of is at a high level.

FIG. 2 is a time chart for explaining the situation, where "V (2)" is the power supply line 20 (2).
Output voltage “V (1)” is the power supply line 20 (1)
Respectively, the output voltage of the capacitor 25 is represented by "Vc (25)", and "Vdiff (1,2)
9) ”indicates the potential difference between the power supply line 20 (1) and the line 29.

By the way, when the lamp is turned on, the relationship between the voltage direction of the starting pulse and the subsequent direction of the lamp current has a great influence on the lighting property of the lamp. For example, as shown by an arrow A in FIG. If the starting pulse is generated with a positive voltage, the voltage V of the power supply line 20 (2) is
(2) is at a high level (voltage V of the power supply line 20 (1)
On the contrary, (1) becomes a low level. ), It is verified that the transition from glow discharge to arc discharge is more likely to occur in the case of the opposite phase, and based on this finding, the above lighting circuit 1 has the voltage direction of the starting pulse and the voltage of the rectangular wave. It is configured to have a specific relationship with the phase.

As shown in FIG. 2, V which is a rectangular wave output
(2) and V (1) have an antiphase relationship with each other and have a rectangular wave shape with an amplitude e.

The output voltage of the winding 7c and the rectifying circuit 11 is v
(> E), the terminal voltage Vc (2
In 5), the voltage rises up to the maximum voltage v + e with a time constant determined by the capacitance of the capacitor 25 and the resistance value of the resistor 26. However, when the capacitor 25 is charged, the terminal voltage Vc (25) approaches the voltage v. When V (2) is high, the capacitor 25 is not charged during the period when V (2) is high.

That is, the line 29 and the power feeding line 20 (1)
As shown in the figure, the potential difference Vdiff (1, 29) between the peak potential v and the potential difference Vdiff (1, 29) is v
+ E, and when V (2) is at a low level, the bottom value becomes a rectangular wave shape of v−e, and after the terminal voltage of the capacitor 25 exceeds v−e, V (2) is at a high level. Only during the period, the capacitor 25 is charged, and the terminal voltage Vc (25) thereof rises stepwise.

Therefore, if an element is selected so that the self-breakdown type switching element 24 breaks down at the voltage v, "x" is shown in FIG.
As shown by the mark, the terminal voltage Vc (25) of the capacitor 25
A pulse for starting is generated immediately after V exceeds v, and this time is limited to the period when V (2) is at a high level.

[0038]

As is apparent from the above description, according to the lighting circuit of the vehicle discharge lamp of the present invention, the starting pulse generating circuit is provided on the secondary side of the DC boosting circuit. A rectifier circuit at a subsequent stage, a capacitor charged by a resistance and a diode by an output of the rectifier circuit, and a primary of a transformer of a starting pulse generating circuit when a terminal voltage of the capacitor reaches a predetermined value. By using the self-breakdown type switch element for generating the pulse in the winding, the circuit can be simplified and the constituent element that causes the delay of the generation of the starting pulse can be eliminated.

Then, only when the voltage difference between the voltage related to the power supply line on which the secondary winding of the transformer of the starting pulse generating circuit is provided and the positive side output of the rectifying circuit exceeds a predetermined level. The charging period is limited so that the capacitor is charged, and the starting pulse is generated only during the charging period, and the starting point of the starting pulse and the specific phase of the output voltage of the DC-AC conversion circuit By providing a relationship between the discharge lamp and the discharge lamp, the transition from glow discharge to arc discharge of the discharge lamp can be facilitated and stable lighting can be guaranteed.

The specific circuit configurations shown in the above embodiments are merely examples for embodying the present invention, and the technical scope of the present invention is limitedly interpreted by these. Not something.

[Brief description of drawings]

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

FIG. 2 is a time chart diagram for explaining the operation of the lighting circuit of the vehicle discharge lamp according to the present invention.

FIG. 3 is a circuit diagram showing an example of a lighting circuit of a conventional vehicle discharge lamp.

FIG. 4 is a circuit diagram showing an improved example.

[Explanation of symbols]

 1 Vehicle Discharge Lamp Lighting Circuit 6 DC Booster Circuit 7 Transformer 7b Power Supply Winding 7c Starting Winding 11 Rectifier Circuit 16 DC-AC Converter 20 (1) First Power Supply Line 20 (2) Second Power Supply Line 21 Discharge lamp (metal halide lamp) 22 Starting pulse generation circuit 23 Transformer 23a Primary winding 23b Secondary winding 24 Self-breakdown switch element 25 Capacitor 27 Resistor 28 Diode

Claims (1)

[Claims] 1. A DC boosting circuit for boosting a DC input voltage by using a transformer, and a DC-AC converting unit for converting an output voltage of the DC boosting circuit into an AC voltage and supplying the AC voltage to a discharge lamp. In a lighting circuit for a vehicle discharge lamp, which comprises a starting pulse generating circuit for generating a starting pulse for the discharge lamp and superimposing this on the output of the DC-AC converting means and supplying it to the discharge lamp, On the secondary side of the transformer of the DC booster circuit, a starting winding different from the winding for supplying power to the discharge lamp is provided, and a rectifying circuit for rectifying the output voltage of the starting winding is provided. (B) The starting pulse generating circuit has a transformer, the secondary winding of which is provided on the first power supply line connecting the output terminal of the DC-AC converting circuit and the discharge lamp, and the primary winding of the transformer. Capacitor and self-breakdown switch in series with line An element is connected, and a series circuit consisting of the element, the primary winding, and the capacitor is closed when the self-breakdown type switch element breaks down. It is connected between the self-breakdown type switch element and the capacitor via a directional diode, and the other output terminal of the rectifier circuit is connected to the second power supply line connecting the output terminal of the DC-AC conversion circuit and the discharge lamp. That is, the breakdown point of the self-breakdown type switching device of (d) and (b) is not less than the difference voltage between the output voltage of the rectifier circuit of (a) and the output voltage of the DC-AC conversion circuit. A lighting circuit for a vehicle discharge lamp, wherein the lighting circuit is set to a range equal to or lower than the sum voltage of the two.