NO141222B - TRAFFIC BARRIER EQUIPMENT. - Google Patents

Description

Electric ignition device with capacitor for firing igniter chains with high ignition pulse energy.

For electric ignition of lighters where

the ignition pulse required to trigger the explosion is large compared to ordinary bridge igniters, great demands are placed on the igniter's contact device.

It is known on this occasion to take

the ignition pulse necessary for igniting such lighters from a capacitor which is charged by an e.g. spring- or hand-operated permanent magnet generator with voltage-doubling coupling.

All capacitor-ignition machines known to date for such igniters work with a mechanical contact device which, for impeccable contact, requires great mechanical precision or in the long run is exposed to strong wear when, as is well known, spark discharges occur.

The purpose of the invention is to avoid these difficulties. According to the invention, this happens by the capacitor's discharge circuit containing two or more discharge tubes, spark paths, whose combined ignition voltage is above the capacitor voltage and a high-resistance resistor can be connected for parallel connection across one or more of the discharge tubes, in such a way that the ignition voltage is above that in the capacitor circuit remaining discharge tube is below the capacitor voltage. The resistance in these connecting elements is infinitely large until their ignition voltage occurs, when no current flows. The ignition voltage for the series-connected discharge tubes, etc., is several hundred volts above the capacitor voltage required for the ignition pulse.

If one saw when operating the generator

charges the capacitor on an equivalent

voltage specified e.g. by means of a voltmeter or an indicator glow lamp, then by connecting one or more of the discharge tubes in parallel with the aid of a high-ohmic resistor, the entire capacitor voltage can be applied to the remaining tube so that the ignition voltage of this tube is below the capacitor voltage. When this tube ignites, the tubes in series will also achieve sufficient ignition voltage so that this tube also ignites and the one for the ignition of

the explosive charge required ignition pulse flows from the capacitor over the ignited discharge tubes to the ignition chain.

This parallel connection of one or more voltage arresters, necessary for triggering the ignition pulses, can be done in the simplest way by operating a push button contact. If, as extra security, the connection to the ignition circuit is only made at the moment of firing, then a switch in the de-energized state can connect the charged capacitor with the voltage arresters to the terminals of the ignition machine and with the help of an additional, i.e. when the ignition circuit is already connected, additional contact provide the parallel connection of one or more voltage arresters.

If the release of the shot is to occur when the required capacitor voltage is reached, regardless of instructions by means of a voltmeter or indicator glow tube, the parallel connection of the voltage arresters can be done by means of a per se known flip-flop connection over a relay contact.

For use of the igniter in potentially explosive pits, it is necessary

you to limit the duration of the ignition pulse to a specific value. This happens with the help of the so-called other contact which in the case of a short-circuit or interruption of ignition current

but determines a desired duration of the ignition pulse. This can be arranged according to the invention in the following way. In terms of experience, the contact stress when disconnecting a capacity, in contrast to connecting, is relatively small. If the contact is designed as a vacuum contact, a momentary opening of the contact occurs,

i.e. within a range of (in sec. without damage

good spark formation.

Some design examples shall be explained

detailed with reference to the design

gene where fig. 1-5 show connection diagrams for different designs of the ignition device according to the invention.

The one in fig. 1 showed capacitor C as

charged up to the required ignition voltage, which is indicated using the voltmeter V el-

ler indicator glow lamp G, with its relative resistance Rv, is in series with the discharge tubes EL 1 and EL 2 and above the terminal

but K with the timing chain which is implied as an external resistance R;l. The ignition voltage for the discharge tubes ELI -f EL2 is large in relation to the capacitor voltage. When operating the switch T, a high-resistance resistor R is connected in parallel with the discharge tube EL 1 and the capacitor voltage U(. is

then across the tube EL 2. This voltage is sufficient to light the tube EL 2 and when the switch T is opened the capacitor voltage will

gene be placed over the tube EL 1 which likewise ignites, after which the ignition pulse over the clamp

but K is applied to the ignition chain R.,. When I-

net dimensioning of a resistor R,,

which shunts the terminals K, it is possible to operate the ignition device with open terminals

more K. The residual energy from the capacitor C is then built up over the resistance Re.

At the one in fig. 2 showed series connection of

several discharge tubes EL 1, EL 2, EL 3, the firing of the shot takes place by operating the two-pole switch T, which parallels the resistors R, and R, with the discharge tubes EL 1 and EL 2, respectively, as described

know with reference to fig. 1.

In the design example according to fig. 3

When the capacitor voltage is reached, which is indicated by means of the voltmeter V or the indicator glow lamp G, by operating the switch Sch, the capacitor C and the discharge tubes EL 1 and EL 2 are connected to the ignition chain Ra via the contacts S, and S...

The contacts S, and S are on the same switch shaft as the contact Sk, but the latter is connected after the two former as explained with reference to that in fig. 1 described course of the shot release.

An implementation example with time-limited

ning of the ignition pulse, for use in an ignition device for explosive pits, shall be explained with reference to fig. 4.

After charging the capacitor C

as described above, by operating the switch T the release of the shot is brought about and at the same time it will

ing of the relay Vs across its contact R, which is preferably designed as a vacuum switch, a time limitation of current pulses can be achieved

Late. The resistance Re here also offers the possibility that the residual charge in the capacitor C can be diverted. These designs can by

a connection which is independent of indication by means of voltmeter V or indicator-glow lamp G,, is realized by means of a known toggle connection which controls the switch T

via a relay contact.

Fig. 5 shows a further embodiment whose structure is in accordance with fig. 1. In this case, however, the release of the shot occurs automatically by operating the switch rk after the capacitor has reached its full charge, as there is a flip-flop circuit Ck, Glk, and the relay Vk whose contact rk at the end of charging the capacitor C parallel cop-

connects the tube EL 1 with the resistor R so that the ignition sequence is triggered.

In all the described design examples, the operation of the switch T can of course take place by means of a relay con-

takt rk which is controlled by a flip-flop circuit.

Claims (4)

1. Electric ignition device with a capacitor for firing igniter chains with high ignition pulse energy, characterized in that the capacitor's discharge circuit contains two or more discharge tubes (ELI, EL2), spark paths or the like, whose total ignition voltage is above the capacitor voltage, and a switchable high-ohmic resistor (R ) for parallel connection over one or more of the discharge tubes, on the way that the ignition voltage across the discharge tube remaining in the capacitor circuit is below the capacitor voltage. 2. Device according to claim 1, characterized by a contact arm (Sk) arranged for connecting the high-resistance parallel resistor (R) which is placed on the same switch shaft as the contacts (Sl, S2) for connecting the ignition chain to the device's terminals (K ) (fig. 3), so that the capacitor (C) can only be discharged over the ignition circuit after it has been sufficiently charged (fig. 3). 3. Device according to claims 1 and 2, characterized by a relay (Vs) which is energized from the capacitor (C) above the discharge tube after the parallel connection of the high-ohmic resistance (R) to the discharge tube, and which causes time limitation of the ignition pulse, which relay has a contact device (r), preferably designed as a vacuum switch, which causes disconnecting the capacitor (C) from the clamps (K) (fig. 4). 4. Device according to claims 1-3, characterized by a flip-flop circuit (Ck, Gl,., Vk) whose capacitor (Ck) is charged simultaneously with the capacitor (C) and discharged through a glow lamp (Glk), which flip-flop circuit initiates the release of the shot and energizes a relay (Vk) which operates a release contact (rk) (Fig. 5). IN