KR0136284Y1 - High pressure trigger pulse generating circuit - Google Patents

Abstract

1. TECHNICAL FIELD OF THE INVENTION

The present invention relates to a circuit for reducing the capacity of the transformer by canceling the excitation magnetic force according to the unidirectional current of the transformer in the high-voltage trigger pulse generation circuit.

2. The technical problem the invention is trying to solve

The high pressure pulse generating transformer for boosting current has a unidirectional current (I ₂ , I ₄ ) flowing therein, and when the unidirectional current (I ₂ , I ₄ ) is 0, an excitation magnetic force exists due to the core characteristic of the transformer. It solves the problem that the change range becomes narrow and the allowable capacity becomes small, and also solves the problem that the possibility of saturation of the magnetic flux density becomes high.

3. Summary of solution of design

In order to increase the allowable capacity of the boost transformer and to prevent saturation of the transformer, a circuit for expanding the magnetic flux density variation of the energized transformer is provided.

4. Important uses of the devise

High voltage trigger pulse generation circuit.

Description

High Voltage Trigger Pulse Generation Circuit

1 is a circuit for generating a conventional high voltage trigger.

2 is a circuit for generating a high voltage trigger according to the present invention.

Figure 3a is a hysteresis curve of a conventional trans core portion.

Figure 3b is a hysteresis curve of the trans core portion according to the present invention.

* Explanation of symbols for main parts of the drawings

4,12,16 Capacitor 6: Transistor

8: additional resistance 22,24: transformer

10 diode 14 spark gap

18 lamp power supply device 20 lamp

The present invention relates to a circuit for reducing the capacity of the transformer by canceling the excitation magnetic force according to the unidirectional current of the transformer in the high-voltage trigger pulse generation circuit.

FIG. 1 is a conventional high voltage trigger pulse generating circuit. First, a high-voltage pulse of a charging circuit resistor 2, a capacitor 4, a discharge control transistor 6, a primary boosting transformer 22 and a transformer 22 is shown. The rectifier diode 10, the charging capacitor 12, and the secondary boost transformer 24 are comprised. At this time, the operation of the circuit having the above configuration will be described. First, when an input power is applied, the capacitor 4 is charged through the resistor 2. At this time, when the capacitor 4 is fully charged, the voltage charged to the capacitor is discharged by the trigger pulse supplied to the base of the transistor 6, and the voltage of the trigger pulse input to the base terminal of the transistor 6 is discharged. by a momentary discharge current (l2) by a change, and the organic to the secondary side (L _l2) of the transformer (22) interconnecting the rectifier diode (10) is filled (l3) in the condenser (12). At this time, since the boosted and charged current is not as large as desired, the above operation is repeatedly charged several times. Then, when a constant voltage (3 KV) or more is applied to the spark gap (SPARK GAP) at the rear end, the secondary 14 (L ₂₃ ) of the transformer 24 is changed by turning on the current 14 discharged from the capacitor 12. Is organic). At this time, the high voltage pulse which is boosted and induced momentarily causes the initial light of the high voltage lamp. Thereafter, the initially lit lamp continues to be lit through the lamp supply power source 18. However, the step-up transformer for generating high voltage pulses 22 and 24 are one-way electric current (I _2, I ₄₎ that flows there the unidirectional current (I _2, I ₄₎ is zero when the core of the transformer (22, 24) Due to the characteristics of the excitation magnetic force is present, there is a problem that the magnetic flux change range of the transformer is narrowed, the allowable capacity is small, and the possibility that the magnetic flux density is saturated increases.

Accordingly, an object of the present invention is to provide a circuit for increasing the allowable capacity of a boost transformer as a high-voltage trigger pulse generating circuit and expanding a magnetic flux density variation range of an energized transformer to prevent saturation of the transformer.

As described above, the present invention provides a circuit for generating a high voltage trigger pulse,

A first capacitor (2) and a second resistor (8) for distributing the power when the power is input, a first capacitor (4) for receiving the power through the first resistor (2) and charging for a predetermined time period; A first transformer that induces a predetermined current to the secondary side through the primary winding and boosts the voltage to a predetermined level or more, and performs an on / off switching operation by receiving a predetermined trigger pulse, and when switching on to the first capacitor Switching means for applying a charged charging current to the core of the first transformer and applying a current flowing through the second resistor to the core of the first transformer in a direction opposite to the direction of the charging current when switching to off; 22).

Hereinafter, with reference to the accompanying drawings of the present invention will be described in detail.

1 is a circuit for generating a conventional high pressure trigger.

2 is a circuit for generating a high pressure trigger according to the present invention,

In the circuit for generating a high voltage trigger pulse,

First (2) and second resistors (8) for distributing power input when power is input;

A first capacitor 4 which receives the power through the first resistor and charges the battery for a predetermined time;

A first transformer 22 for boosting the voltage to a voltage higher than or equal to a predetermined level by inducing a predetermined current to the secondary side through the primary winding;

A predetermined trigger pulse is input to perform an on / off switching operation. When switching on, the charging current charged in the first capacitor 4 is applied to the core of the first transformer 22, and when switching off. Switching means 6 for applying a current flowing through the second resistor 8 to the core of the first transformer 22 in a direction opposite to that of the charging current;

A second capacitor 12 for charging the boosted current,

A spark gap 14 for instantaneously conducting the current when the boosted and charged current is boosted to a predetermined level;

By the instantaneous change, a current is applied to the primary winding, and the applied current is guided to the secondary side to form a second transformer 24 for boosting.

3A is a hysteresis curve of a conventional trans core portion.

Figure 3b is a hysteresis curve of the trans core portion according to the present invention.

Hereinafter, the hysteresis curve of FIG. 3 and the circuit diagram of FIG. 2 attached to the present invention will be described in detail.

When input power is applied, current I ₁ is charged in capacitor 4 through resistor 2. At this time, when the capacitor 4 is fully charged, the voltage charged to the capacitor is discharged by the trigger pulse supplied to the base of the transistor 6, and the voltage of the trigger pulse input to the base terminal of the transistor 6 is discharged. By the change, the instantaneous discharge current I ₂ is stepped up and induced from the primary winding of the first transformer 22 to the secondary winding. At this time, the excitation magnetic force remaining in the core portion of the first transformer 22 after being induced by the secondary winding is connected in parallel with the resistor 2 to the first winding through the primary winding of the first transformer 22. It is canceled by the current I ₂ flowing to the condenser 4. In this case, when the canceling excitation magnetic force is explained in FIG. 3b, the hysteresis curve of the first transformer 22 has a magnetic flux density because a change region exists not only to the right and top sides but also to the left and bottom sides by the current I ₆ . The range of change becomes wider.

Then, the current induced in the secondary winding of the first transformer is first stepped up according to the turns ratio to conduct the rectifying diode 10 to charge the charging current I ₃ to the capacitor 12. At this time, since the boosted and charged current I ₃ does not become as large as desired, the above operation is repeatedly charged several times. Thereafter, when a constant voltage (3KV) or more is applied to the spark gap (14) of the rear stage, the second current (24) is instantaneously changed to discharge the current (I ₄ ) discharged from the capacitor (12). Is induced on the secondary side. At this time, the high voltage pulse which is momentarily stepped up and induced causes the initial lighting of the high voltage lamp. Thereafter, the initially lit lamp continues to be lit through the lamp supply power source 18.

As described above, the present invention provides a circuit for increasing the permissible capacity of a boost transformer as a high-voltage trigger pulse generating circuit and expanding the magnetic flux density variation of the transformer which is excited to prevent saturation of the transformer, and thus, per unit area of the transformer. There is an advantage to increase the capacity.

Claims (2)

A circuit for generating a high voltage trigger pulse, comprising: first and second resistors for distributing power when power is input, a first capacitor for receiving a power through the first resistor and charging the battery for a predetermined time; A first transformer that induces a current to the secondary side through the primary winding and boosts the voltage to a predetermined level or more, and performs an on / off switching operation by receiving a predetermined trigger pulse, and when the switch is turned on, the first capacitor is charged. And switching means for applying a charging current to the core of the first transformer and applying a current flowing through the second resistor to the core of the first transformer in a direction opposite to the charging current when switching off. High voltage trigger pulse generation circuit. The method of claim 1, further comprising: a second capacitor for charging the boosted current, a spark gap for conducting the current instantaneously when the boosted and charged current is boosted to a predetermined level, and 1 by the instantaneous change; And a second transformer for applying a current to the secondary winding and inducing the boosted current to the secondary side to boost the secondary winding.