DE2047150C3 - Condenser ignition device - Google Patents

Description

Capacitor ignition device, voltage built up with a voltage saior stored charge

source, with an ignition of the spark discharge gap connected to the voltage source is sufficient

closed first capacitor, which must have a first.

Control discharge path parallel to at least one. The object of the invention is switchable with a spark discharge path, with a circuit arrangement of the type mentioned above, also connected to the voltage source, in that its structure is to be simplified and a capacitor connected to a second control discharge 4 ° that it so should be designed that the control part is connected to the route through which the first control control of the discharge of the first capacitor discharge path in the breakdown voltage range via the first control discharge path is only richly controllable, and with a transformer, a fraction of the discharge energy is exposed.
its secondary winding between the first control. According to the invention, this object is achieved by the discharge path and the spark discharge path 45 in that the breakdown voltage of the second is switched. Control discharge path smaller than that of the first. Such an electrical capacitor ignition device control discharge path is known that the second condensation is known (US Pat. No. 3,450,942). The main patent 2 046 913 relates to an electrical series with the first capacitor switchable and Irish capacitor ignition device with a voltage source connected to the primary winding of the transformer with the voltage source connected to the second Control discharge path in series closed first capacitor, which is connected in series via a switchable capacitor, first control discharge path in parallel with at least which series connection can be switched in parallel with the first control of a spark discharge path, and discharge path is switched.

one also connected to the voltage source. 55 In this arrangement, the second control device is

senen second capacitor, which is connected to a second control charge path for only a fraction of the discharge current

Discharge path is connected, through which that of the first capacitor is exposed and is therefore

first control discharge path in the breakdown voltage very little loaded during operation. At the

voltage range is controllable, and is characterized by the breakthrough of the second control discharge path

draws that the breakdown voltage of the second 60 connected the capacitors in series for a short time.

Control discharge path smaller than that of the first The added voltages of the capacitors over-

Control discharge path and that the second con- rise the breakdown voltage of the first control

capacitor discharge path by means of the second control discharge path, so that it is controlled through,

can be switched in series with the first capacitor, the discharge of the series-connected capacitors

which series connection then parallel to the first 65 capacitors across the primary winding of the transformer

Control discharge path is switched. and the second control discharge path to ground

In the case of the US Pat. No. 3,450,942, one induces in the secondary winding one for the

known circuit arrangement, the second breakthrough in the spark discharge gap is sufficient-

de high tension. After the breakthrough of the left discharge path, the can then be used as a storage capacitor serving first capacitor via the first control discharge path and the secondary winding deliver its energy to the spark discharge gap.

The invention is hereinafter based on the Drawing described in more detail. The drawing shows the sdialt diagram of an exemplary embodiment.

The circuit arrangement shown in the drawing is for use as a capacitor ignition device designed for jet and gas turbine engines. However, the invention is based on this application -, - art or such investments are not restricted.

The capacitor ignition device shown is powered by a suitable voltage source 13. z. B. an AC voltage source or a chopper, energized, wherein the voltage is applied to input terminals A and B of the ignition device. The voltage source 13 is connected to the primary winding 10 of an input power transformer 11, the secondary winding of which is denoted by 12. The circuit arrangement also contains a high-frequency filter 14, which is preferably used and is connected between the voltage source 13 and the transformer 11 to attenuate the high-frequency noise generated in the ignition device, so that interference cannot be transmitted to those circuit elements that are connected downstream of the power supply.

A memory operating as a voltage doubler is parallel to the secondary winding 12 of the transformer 11 switched. This energy storage device is gradually replaced by the voltage source via the Transformer 11 charged; the energy store is periodically connected to a pulse-receiving load in Discharge in the form of a spark discharge gap 29. The memory consists of a proportionate large first capacitor 20 (storage capacitor), a small one, via a diode 16 parallel to zr.r Secondary winding 12 connected capacitor 15, another small one, opposite one another polarized diode 19 parallel to the secondary winding 12 connected capacitor 17, the first capacitor 20 is connected in series with the capacitors 15 and 17. If with the circuit shown of the diodes 16 and 19 the capacitors are charged, so are the lower terminals of the capacitors 15, 17 and 20 have negative poles, while at the lower terminal one described below Capacitor 31 has a positive potential. By limiting resistors 21 and 22, the diodes and 19 can be protected against damage, their service life can be extended and their rated load can be extended can be reduced. One side of the energy storage device described above is on a ground point 23 is connected, and its high-voltage side is connected via a first control discharge path 25 is connected to the ungrounded electrode of the spark discharge gap 29. If it is appropriate appears, all ground points 23 can be connected to one another by a common ungrounded line will.

The input electrode 24 of the first control discharge path 25 is on the high voltage side via the first capacitor 20 (storage capacitor) connected to the ignition circuit. The output electrode 26 the first control discharge path 25 is connected to a terminal of the secondary winding 27 of a step-up transformer * 28 out, while the other terminal of the secondary winding 27 to the ungrounded Electrode of spark gap 29 connected is.

A series circuit is located parallel to the electrodes 24 and 26 of the first control discharge path 25 from a large resistor 30 and the small capacitor 31. If necessary, this A choke coil 32 is added in series. Between the connection point of the choke coil 32 and the input terminal of the secondary winding 27 de >> Transformer 28 is on the high voltage side a terminal of a small Wuier stand 33 switched, the other terminal of which is connected to ground. One terminal of the primary winding 35 of the step-up transformer ^ 28 is between the Resistor 30 and capacitor 31 are connected, and the other Klemnv * of the primary winding 35 is

to the input electrode 34 of a second control discharge path 36, the output electrode of which 37 is grounded. The breakdown voltage of the second control discharge path 36 is considerable smaller than that of the first control discharge path 25

and much smaller than that of the spark discharge path 29.

In one embodiment of the invention, the power transformer 11 transforms the supply voltage from, for example, 400 Hz 115 V to 3- 'over 1400 V _s . Each half cycle of this voltage is rectified by one of the diodes 16 and 19 to charge one of the doubling capacitors 15 and 17. The voltage applied to the capacitors 15 and 17 has an additive effect, and therefore the charging voltage of the first capacitor 20 (storage capacitor) and of the trigger capacitor 31 is more than 2500 V.

During the charging of the first capacitor 20, the capacitor 31 connected in parallel with it becomes charged via the resistor 30, the charging circuit for the capacitor 31 via the choke coil 32 and the resistor 33 is connected to ground. When the diodes 16 and 19 are switched according to the drawing are, the input electrode 24 of the first control discharge path 25 is opposite the output electrode 26 positive. When the second control discharge path 36 is breached, the positive side becomes of the capacitor 31, i.e. the one with the electrode 34 of the second control discharge path 36 via the primary winding 35 connected side, briefly grounded, whereby the capacitors 20 and 31 briefly are connected in series via the second control discharge path 36 and the voltages of the capacitors Add 20 and 31. This means that the added voltages exceed the breakdown potential of the first control discharge path 25 of 3500 V, whereby this control discharge path durchgcstcuert and the storage capacitor 20 is discharged. The subsequent discharge of the series-connected Capacitors 20 and 31 via the primary winding 35 of the transistor 28 and the second control discharge path 36 to ground leads to a stepped-up voltage across the secondary winding 27 of transformer 28. This high voltage of the order of 15 to 20 kV is also called the Output cable and the spark discharge gap 29 (z. B. a spark plug) impressed. If once over the spark discharge path of the initial light

5 6

arc has formed, the in the memory ■ ΛIL

capacitor 20 contained energy over the first wave impedance Z = I / - -,

Control discharge path 25, the secondary winding 27 '

of the transformer 28 and the ^ur > d already formed

Arc of the spark discharge gap 29 to ground 5 current / = ^

derived. ~ \ / L

This energy is called "follow-up energy". After- I /

the voltages on the two capacitors 20 t C

and 31 have dropped to low values, “,. , _. , _ ... _

the associated control discharge paths 25, 36 un- > o capacitors 15 and 17 ... 0.06; iF

ionized, and the cycle of operation is repeated. Capacitor 20 3.5 to 36 mF

In the circuit arrangement according to the invention capacitor 31 0.05 to 0.06 μΡ

the second control discharge path 36 controls the QI ₁₁₁₁

Breakthrough of the first control discharge path 25. Resistors 21 and 22 .... 2,000

The normal breakdown voltage of the first control 15 resistor 30 25 000

discharge path 25 is much higher than their trigger resistance 33 '. "". 2,500

level. In the circuit arrangement according to the invention, the second control discharge path 36 is only a breakdown voltage 5% of the energy that is exposed over the first control discharge path 25 .. 3000 V Control discharge path 25 discharges. This results in »o control discharge path 36 .. 3500 to 4000 V the service life of the second control discharge path

36 increased significantly. The discharge of the two in addition to the above execution series switched capacitors 20 and 31 via example of the invention are still more possible, the primary winding of the transformer 28 allows, for example, the storage capacitor 20 step, the required high voltage on the secondary 35 by other known voltage doublers winding with the minimum number of turns. or half-wave rectifiers. This This results in an increased current flow and thereby capacitor can, for. B. directly from the secondary one maximum output power. winding of the AC voltage-driven upward

The characteristic values which the vorste-transformer are charged. Furthermore can

components 30 of FIG.

are the following: voltage operated.

1 sheet of drawings

Claims (1)

1 2 Capacitor after reaching the breakthrough voltage Claim: ruing the second control discharge line over the First half of the winding of a choke with a central electrical capacitor ignition device, with tapping, via the primary winding of the transformer, a voltage source, with one to the tensioner and a third capacitor. The second voltage source connected to the first capacitor, winding half of the choke, is connected to a jacket which is parallel to at least one spark discharge envelope of the first control discharge path and is connected via a first control discharge path and made of a conductive material. with a also connected, via which the first capacitor (storage device connected to the voltage source capacitor) to the spark discharge path switch, which is connected to a second control discharge path. The discharge current of the second capacitor, through which the first control capacitor is connected, generates a relatively high charging path in the breakdown voltage across the choke, which can be controlled between the envelope and the area. and with a transformer. one electrode of the first control discharge path, the secondary winding of which lies between the first control discharge path, so that the path between the two electrical discharge paths and the spark discharge electrodes is ionized and the breakdown voltage value path is switched, thereby being markedly reduced. As soon as the breakdown voltage of the drawing 1, that the breakdown voltage of the first control discharge path is reached, the second control discharge path (36) discharges smaller than the first capacitor via the secondary winding that of the first control discharge path (25), 20 of the transformer and the spark discharge path that the second Capacitor (31) by means of the The jacket-shaped envelope of the first control separated control discharge path (36) in series with the charge path, the choke with center tap of the first capacitor (20) and between the second discharge path and this that the primary winding (35; the transformer center electrode and the additional capacitor in (28) with the path (36) which can be connected in series capacitors to a complicated control circuit and thus to (20, 31) is connected in series, which series one elaborate condensate ignition device,
circuit parallel to the first control discharge In the ignition device according to the main patent (25) is connected. is the breakdown voltage of the second control 30 discharge distance smaller than that of the first control discharge distance. The first capacitor will, however connected directly parallel to the spark discharge path The invention relates to an electrical tet, so that the through the first condenser