DE717335C - Temporary switch, especially for spot welding machines - Google Patents

Description

Short-time switch, especially for spot welding machines. The invention refers to the known time switching devices, in which one in the grid circle a grid-controlled arc discharge vessel lying capacitor before initiation the time switching process from an AC voltage source via the rectifier path Grid cathode of the discharge vessel is charged and the charging alternating voltage is dimensioned such that the discharge vessel before and after your time switching process is kept conductive. When the time switching process is initiated, the alternating voltage, which is used to charge the capacitor and to ignite the discharge vessel, lowered below the voltage of the charged capacitor, so that the discharge vessel goes out and is held blocked by the voltage of the previously charged capacitor will. During the timing process, the capacitor gradually overdischarges an adjustable resistor in such a way that after the time has elapsed the discharge vessel is re-ignited: Time switching devices of this type can be used with advantage in the Way to be used that via the grid-controlled arc discharge vessel the excitation circuit of a relay is controlled, which in turn switches on and off an electrical power consumer causes, for example a welding transformer energizing electromagnetic switch.

The invention relates to an improvement of the diesel principle based Time switching devices with the aim of increasing the accuracy of the time determination. According to the invention, the alternating voltage charging the capacitor is on initiation of the time switching process initially only by a small amount; -the re-ignition of the discharge vessel just preventive amount and only by the extinguishing of the discharge vessel on one compared to the capacitor voltage decreased small value. It is therefore for the invention essentially that the alternating voltage, which the grid capacitor Charges the grid-cathode via the rectifier section when the time switching process is initiated not switched off immediately or on one as with known time switch arrangements compared to the direct voltage bz «-. Charging voltage of the capacitor is reduced by a small value will; in the invention, instead, the alternating voltage charging the capacitor is used initially only reduced by such an amount that the arc discharge vessel goes out. The alternating voltage is only activated when the discharge vessel has gone out further reduced. This is advantageously done by placing one in the anode circuit of the discharge capable lying relay, its normally open contact at the same time switches on the discharge circuit of the capacitor.

Further details and further features of the invention result from the description of the embodiment shown in the drawing.

To the terminals i and 2 of an alternating current source, the voltage thereof, for example 38o volts, the primary winding of a welding transformer is via fuses goi 7 'connected. The transformer is through the working contacts ioi of an electromagnetic Switch of the contactor ioo, switched on and off. The excitation coil of the contactor ioo is one via a manually operated control switch S and the normally open contact ao2 Auxiliary relay Zoo connected to AC power source 1, 2. The auxiliary relay aoo is advantageously designed as a vacuum relay and via a grid-controlled mercury vapor discharge vessel St connected to the = 2o Voltali tap of a 30o transformer. The working contact : 2o2 of the auxiliary relay 200 is connected to the contactor coil roo in such a way that the contactor is switched on as long as the excitation circuit of the auxiliary relay Zoo is switched off, d. H. so as long as the discharge vessel St is blocked. In the idle state of the switching device, d. H. before and after the time switching process, the discharge vessel St is therefore conductive.

Various time ranges of the time switch can be set by means of a hand-held control switch, which can be designed as a packet switch. This packet switch has five parts P1 to P; with four switch positions each oI-II-III. In the switching position o, which is drawn in the circuit diagram, the discharge vessel St and the auxiliary relay are disabled; Glass contactor iöo is only switched on and off by the control switch S, the duration of the switch-on depends on the duration of the. Actuation of the control switch S. In each of the switching positions I, II and III, dai: against the switch-on time of the contactor ior, is determined by the control circuit of the discharge vessel i-Pes St. These switch positions differ from one another only in that different time ranges are set. The total time range can be changed from 1 to 100 periods.

In the grid circle of the grid-controlled mercury vapor discharge vessel A capacitor 503 is connected to the control grid via a grid series resistor 607 connected is. In parallel with the capacitor there is a circuit that determines the switching time Discharge circuit, which consists of the fixed resistance levels 604th, 6o5, 6o6 and a adjustable resistance component 701 exists. Through part P ,, of the package counter P, the resistors 604. and 6o5 can optionally be short-circuited «-earth. Switched on the discharge circuit of the capacitor 503 is through the normally open contact 201 of the vacuum relay This normally open contact closes the discharge circuit as long as the vacuum relay is active or the discharge vessel .St is blocked.

To charge the capacitor 503 , an alternating voltage is used which leads the anode voltage of the discharge vessel .S't in phase, preferably by about 15 °. For this purpose parallel to the discharge vessel St and the relay 2no the series circuit of a capacitor and a resistor 602. The 5oi connection point d.oo between these two is connected to the facing away from the control grid availability d capacitor connected 503rd Depending on the position of the relay 20o, this connection is made directly via its normally open contact Zoo or via the resistors 6 () 9 and 61o. The latter resistance can be provided by the part P i; of the packet switch are short-circuited.

When changing from switch position o to switch position I of the package switch: the following switch connections are made. The switch part P 1 connects the cathode of the discharge vessel St to the transformer 300 and thereby switches on the anode voltage of the discharge vessel. The switch part P2 connects the. Capacitor 503 via a resistor 6o8 to the control switch S and via this to the cathode of the discharge vessel St or to the transformer 3oo. The switch part P, cancels a short circuit of the normally open contact 202 of the relay Zoo and thereby makes (read contactor ioo dependent on the switch position of this normally open contact ao2.

The operation of the circuit described above is as follows: In the drawn zero position of the package switch P, the contactor ioo is above the manually operated control switch S directly to the AC voltage i, 2. The The contactor coil can be switched on for any length of time using the control switch S.

If you want to switch to automatic time control, the package switch P is switched to switch position I. As a result, the discharge vessel St and the relay 200 are connected to the 22o volt tap of the transformer 3oo. At the same time, the control grid of the discharge vessel receives an AC voltage that leads the anode voltage via the two resistors 607 and 609 and the still uncharged capacitor 503. The discharge vessel St ignites and switches on the circuit of the vacuum relay 200. The normally open contact of this relay opens the discharge circuit of the capacitor 503 and also shorts the resistor 6o9. The normally open contact 2o2 of the relay opens the connection line between the control switch S and the contactor ioo. The capacitor 503 is now charged with a voltage of about 50 volts, via the rectifier stretch of the grid cathode of the discharge vessel St. Since the capacitor cannot be fully charged to the peak value of the alternating voltage, the grid potential is in positive over a relatively wide time range in the vicinity of the peak value of the charging voltage. The arc discharge vessel St is practically fully controlled, since the charging voltage leads the anode voltage by about 5 °. The discharge vessel is kept ignited continuously in this switch position. The time switching device is now prepared for the initiation of a time switching process.

As soon as the manually operated control switch S is closed, which is usually also connected with the closing of the electrode circuit of the welding transformer, the resistor 6o8 is connected in parallel to the resistor 6o2. The voltage across these two resistors. is thereby reduced by a certain amount, since the capacitor 501 is connected upstream of them. Since the voltage of the resistor 602 is at the same time the charging voltage of the capacitor 503 , this voltage is reduced. The ratio of the two resistors 602 and 608 is dimensioned such that the voltage is reduced by so much that it is no longer sufficient to make the grid of the discharge vessel St positive with respect to the cathode. The negative direct voltage of the charged capacitor is now greater than the positive peak value of the alternating voltage of the resistor 602. This change in the charging voltage has the consequence that the discharge vessel St goes out at the next zero crossing of its anode current. The next positive half-wave no longer ignites.

The time switching process is not yet initiated at this point, since the relay aoo in the anode circuit of the discharge vessel St has not dropped out. is. It is essential that the start of the fall time of this relay is from the point in time the operation of the control switch S is independent. The fall time is only just beginning when the anode current of the discharge vessel St goes out at the end of the half-wave. This deletion time is independent of the closing time of the control switch S always the same. The circuit of the protective coil ioo is thus always in a certain phase time closed when a relay zoo with practically constant Fall time is used. A vacuum relay largely fulfills this requirement. In order to be able to set the fall time, a capacitor 5o2 is connected to the relay Zoo connected in parallel in series with a resistor 6oi.

When the vacuum relay Zoo drops out, not only is the protective coil ioo switched on by the normally open contact 202, but also the discharge circuit of the capacitor 503 is closed at the same time by the normally open contact 201. Finally, the last-mentioned contact toi opens the short circuit of the resistor 6o9. Is now viewed allinählich diminishing DC voltage of the capacitor 503 which is superimposed a small AC voltage to the grid of the discharge vessel St. By connecting the resistor 6o9 upstream of the resistor 6o8, the alternating voltage of the capacitor 503, which was previously reduced by a small amount, is increased by a second. Amount, reduced to such an extent that only an alternating voltage remains which is small compared to the direct voltage component of the capacitor 503. This voltage leads the anode voltage of the discharge vessel St by 4.g ° in phase and ensures that the time of the Reconnection of the discharge vessel is precisely determined by its phase. After the capacitor 503 1 has been sufficiently discharged, the discharge vessel is ignited at the beginning of a positive half-cycle of the anode voltage of the full discharge. Glue igniting the Entladungsgek fies -draws the relay- 2 () 0 again and opens it through its working contact 202 the circuit of the contactor coil 100. At the same time, the discharge circuit of the capacitor 503 is opened by the working contact toi of the relay 200 and because of the short circuit of the resistor 6o9 switched on an increased charging alternating voltage. The capacitor 303 can, however, only be charged to the full voltage range when the Stettersclialter S is opened and the parallel connection of the resistor to the resistor 602 is thereby canceled.

The reduction in the charging voltage, which is essential for the invention of the ILOndensators503 initially only by a small amount, which is an exemplary embodiment by connecting the resistor c- @ fi8 in parallel to your Z @ i @ lerstancl f @ o.:, a reaches wirc1, has the following advantages: Assume that fier control switches during the burning time of the discharge vessel St closed and that, as in known circuits, the AC charging voltage is completely removed, so the capacitor would ; 03 strongly discharged via the grid during the burning time of the discharge vessel St can. That would assure that the time accuracy of this in his Austnat1 does not depend on the unloading process in advance. The invention avoids this disadvantage, because due to the lowering of the charging voltage utn only a minor one Amount of the early discharge of the capacitor; is prevented.

If titan continues to assume that the control switch is actuated after a welding pause that is too short, there is a risk that the timer will be initiated before the charging capacitor can be charged to its full value. The welding time would then be too short. This shortening of the welding time is automatically avoided in the switching device according to the invention in that no welding takes place at all if the capacitor has not yet reached the voltage required for a correct welding time. This can come about in the following way: When the capacitor is discharged, the grid is positive in the positive half-wave around the full charging voltage - compared to the Katbocle. By charging the capacitor I lowers the grid potential and is it on busy s consummate charging only in a small time range near the positive peak value of the charging voltage by an amount -eriiizen positive towards the cathode. L'in; lieen F3etrag is the charging voltage; by Actuation of the control switch .5 ': receivedincrt, and the following half-wave will not inelir ignited. On the other hand, the capacitor is still not sufficiently charged if the tax switch .S is actuated, clie passes through the parallel connection of the Wicierstancles (.o8 brought about a reduction in the charging voltage of the capacitor not off_ to the ignition to prevent the discharge vessel. In in this case the discharge vessel burns ter, and there is no welding urge. It should also be pointed out that the in execution forums shown in the drawing, at which the charging voltage of the capacitor j o3 by connecting the resistor in parallel () o8 to your resistance (, 02 reduced is, nor by other equivalent mean <4 can be replaced. It's just essential, Hall when you close the control switch S` the iionelensator over the rectifier, track Gitt, # r cathode charging AC voltage not taken away immediately, just around reduced by such an amount "- that , just enough, uni the discharge vessel -5 '1 to lock. Also the one shown in the drawing Circuit for winning one of the anode voltage of discharge "efiiVes St in the Plias: c leading up to Z, to larIuii "of the capacitor 503 can through other equivalent and known 1 @ I means for Obtaining a phase-shifted chip can be replaced. It is also not un- conditionally necessary that this tension taken from the same transformer «-ird icie the anode voltage of the discharge g;: fäi: fe ... The circuit shown gave me the advantage part of the simplicity. For the connection of the patent drawing Also mentioned that a resistor Bor is expediently connected in parallel with the contactor coil i,) o so that the estimation coil is protected against excessive voltage when it is switched off. Furthermore, it is advantageous to bridge the contact 2o2 of the vacuum switch 2f) o and the control switch S by a quenching capacitor: # 0d finite series resistor 8o2. The .toi glow discharge path connected in parallel to your vacuum relay? Oo is used to keep inadmissibly high voltages away from clean vacuum relays.

The resistor Oio, which in the circuit c1r patent drawing can be connected in series with the resistor 6 () c) via the part P ~ of the package switch, is used for this purpose. in each of the three time ranges of the Kurzzeitsclialteinrichtung during the discharge of the capacitor 303 to receive a different alternating voltage at the resistor 6o8. The consequence of this is that the alternating voltage superimposed on the discharge voltage of the capacitor has a different size in each time range. In the lower time range it is selected to be large, in the two upper time ranges it is selected to be smaller or completely @voided. As a result, the setting resistor 7oi in the U discharge circuit of the capacitor 503 can have a smaller resistance value than if there is no resistor 61o, without the maximum discharge current in the time circuit increasing at short times. This is because the ignition of the discharge vessel takes place earlier, with the same discharge time constant, the greater the superimposed alternating voltage. A changeover of the time ranges can also be achieved by changing the superimposed alternating voltage.

Claims (6)

PATENT CLAIMS: i. Short-time switch, especially for spot welding machines, at your before the time switching process on! in the grid circle of an arc discharge vessel lying capacitor from an alternating voltage source over the rectifier path The grid cathode is charged and the charging alternating voltage is dimensioned in such a way that that the discharge vessel is kept conductive while the time switching process is initiated the AC voltage is lowered below the voltage of the charged capacitor, so that the discharge vessel goes out, characterized in that the capacitor charging alternating voltage when initiating the time switching process initially only by a small amount that just prevents reignition of the discharge vessel and only through the extinction of the discharge vessel in comparison to that Capacitor voltage is reduced to a small value. 2. Time switch according to claim i, characterized in that the reduction of the alternating charge voltage by the first (small) amount through a manually operated control switch, the reduction by the second (larger) amount, on the other hand, takes place through an auxiliary relay whose excitation circuit is connected to an alternating voltage via the discharge vessel, whereby through this auxiliary relay also has a discharge resistor in parallel with the capacitor switched and the power consumer to be controlled by the timer switched on will. 3. Time switch according to claim 2, characterized in that the excitation coil a contactor for the electricity consumer via a manually operated control switch and a normally open contact of the auxiliary relay is connected to a power source. q .. Time switch according to claim i or 2, characterized in that the capacitor Charging alternating voltage compared to the anode voltage of the discharge vessel in the phase is advanced. 5. A time switch according to claim i or one of the following, characterized in that group), the grid-controlled arc discharge vessel (St) in series with a preferably a vacuum relay formed auxiliary relay (2oo) to an AC voltage (3oo) is connected, the (parallel to vessel St) and relay (20o), the series circuit of a capacitor (50i) and a resistor (6o2), the connection point (d.oo) between these switching elements via a resistor (6o9) and the grid capacitor (503) with the control grid and via a Another resistor (6o8) is connected to the cathode of the discharge vessel (St) and that a working contact (toi) of the auxiliary relay (2oo) short-circuits the resistor (6o9) in front of the capacitor (503) when the relay is switched on and a discharge circuit of the capacitor (5o3 ) opens, while a second working contact (2o2) of the auxiliary relay (2oo) a contact of the manually operated control switch (", S) with the circuit to be controlled (Erre circuit) of a contactor (ioo). 6. Time switch according to claim i or the following, characterized in that to the The excitation coil of the auxiliary relay (2oo) has an adjustable capacitor (502) in series with it a @@ 'iderstand (6oi) is connected in parallel.