DE661342C - Device for electrical spot or spot weld welding using controlled steam or gas discharge paths - Google Patents

Description

The invention relates to control devices for electrical spot welding machines, with the help of which a single rush current or a periodic series of current surges from an alternating current source can be fed forth to the electrodes. The invention enables the flow of the current to be predetermined Points in time of the period of the alternating current independent of the actuation of a mechanical one Switch o. The like. Initiate and interrupt.

There are already converter-controlled electrical spot welding machines known, in which an electrical influence on the welding currents by shifting the phase position of grid and anode voltage the discharge path that regulates the current. The beginning of the flow is done by operating a mechanical switch. This can result in inaccuracies occur in the duration of the current flow up to half a period of the alternating current, depending on which one Moment of the period the switch is closed. The interruptions take place always only after a longer current flow, so these gaps make only one small part compared to the total number of current-carrying periods, so that one Reduction in the energy supplied is not noticeable. For frequent interruptions on the other hand, wherever current only flows for a few or even a single period, there are no longer such gaps to neglect; Rather, they may be the cause of unevenness in the Form weld.

The invention relates to a control device which, in the case of spot or spot weld welding devices periodically increasing and decreasing the current at predetermined intervals of the period of the alternating supply current permitted and even at high working speeds regular periodic Currents and uniform heating results.

In a known manner, there is a series transformer in the primary circuit of the welding transformer provided, the impedance of which can be changed by short-circuiting its secondary winding via vapor or gas-filled discharge paths. According to the invention the grid-controlled discharge paths are controlled with the help of a transformer, the primary winding of which is in a bridge circuit is arranged. One branch of this bridge is held by a resistor and one half of a voltage divider connected to the AC supply voltage formed, while the other branch from the other part of the voltage divider and the primary winding of another Transformer. The latter can be achieved on the secondary side by means of grid-controlled auxiliary discharge paths be short-circuited and

generated at the control grids of the main discharge paths a voltage that can be rotated by almost 180 ° and is used to control the welding current. The auxiliary discharge. *? stretch are for their part again from einjitj Capacitor charging circuit controlled, whereby duirca ' Dimensioning of the elements of the condensate circuit and any desired welding time and by suitable choice of control voltages ίο pause duration can be set.

An advantage of the invention is that the operating speed is not by the Inertia of moving mechanical parts is limited and a synchronous periodic »5 interruption of the welding current can be achieved.

The invention is also applicable when it comes to the welding electrodes single current surges during previously written parts of the period of the alternating supply current and of a prescribed length of time as required for spot welds.

The invention will be explained in more detail with reference to the exemplary embodiments shown in the figures. In the Fig. Ι is an embodiment for the case of a spot weld, while Fig. 2 shows a graphic representation of the decisive Tensions of this device is given. Fig. 3 shows an embodiment of the invention for a machine for resistance spot welding, while in Fig. 4 again a graphic representation of the decisive Tensions of this device is given. In the arrangement shown in Fig. 1 the flow of the current in the welding circuit is controlled by the impedance this circuit is changed with the help of discharge paths, which in turn can be controlled by periodic voltages, which from one to the supply current source connected conversion circuit are generated. The impedance of the welding circuit is changed with the help of a series transformer ι whose primary winding 9 connected in series with the primary winding 7 of the welding transformer 3 and the secondary winding 11 of which is short-circuited by the discharge paths 2 can. The secondary winding 4 of the welding transformer 3 is connected to the welding electrodes 5, between which the workpiece 6 is connected, while the Primary winding 7 via a switch 8 and the primary winding 9 of the transformer 1 is connected to an AC power source 10. When welding seams, it is common to use the To close the welding current after the welding electrodes are pressed, and the Open the welding circuit before pressure is removed from the electrodes. The switch 8 is used for this in the arrangement shown

$ * ■ The secondary winding 11 of the Transforma-4f <Drs I is connected to opposite parallel formed discharge lines 2, which f, 'the anodes 12, cathodes 13 and control electrodes (Control grid) 14 own. Discharge distances of any kind can be taken '7 ° will; discharge paths with arc-like discharge and Steam or gas filling used. The onset of the current can be done with the help of the grid being controlled; has the discharge in the vapor or gas-filled discharge paths once inserted, it cannot be influenced further with the aid of the grid unless the anode voltage is temporarily removed or the Assumes a value of zero. Such a discharge path is controlled periodically Removal of the anode voltage in order to extinguish the discharge and periodically Restart the discharge with the help of the control grid. It is regulated the mean value of the anode current.

The discharge paths 2 are arranged so that they the secondary winding 11 of the Short-circuit series transformer 1 when they are made conductive. By the Short-circuiting the secondary winding of the transformer 1 becomes the impedance of the Primary winding reduced to a very small amount and thereby causes essentially the full load current to the primary winding of the welding transformer 3 can flow.

The discharge paths 2 are controlled with the aid of a grid transformer 15, the secondary windings 16 of which are connected to the grids and cathodes of the discharge paths 2 and the primary winding 17 of which is connected to the impedance 18, which is connected to the supply current source 10 via the conductors 19 and 20. One end 21 of the primary winding of the grid transformer is connected to the center tap 22 of the impedance (choke coil) 18. The other end 23 is connected to the end 25 via a resistor 214 and to the end 29 of the impedance 18 via the primary winding 26 of a transformer 27. By short-circuiting the secondary winding 30 of the transformer 27, the impedance of the primary winding 26 is reduced to a very small amount, and it is characterized, so to speak, the terminal of the primary winding 17 of the grid transformer 15 to the impedance 18 ^au of the terminals 22,25 for the terminals 22, 29 relocated. This will change the phase of the grid voltage

Discharge paths 2 shifted by approximately 180 °. Therefore, when the secondary winding of the transformer 27 is not short-circuited, it is the voltages of the grids 14 of the discharge paths 2 by approximately 180 ° in phase with respect to the anode voltages shifted and as a result the discharge paths are not current-permeable (blocked). When the secondary winding 30 of the transformer 27 is short-circuited, is the phase position of the grid voltage reversed and thereby the current permeability of the Discharge distances caused.

The short-circuiting of the secondary winding 30 of the transformer 27 is done in opposite directions Discharge paths 31 connected in parallel causes. The current permeability of this Discharge paths, in turn, are controlled by a bias voltage and a voltage, which has a greater amplitude and period than the said bias voltage that you counteracts and removed from the deformation circuit containing a discharge path 32 will.

Said conversion circuit (inverter) contains a capacitor 33 or a different type of suitable energy storage, which is periodically under the action of a Discharge path is charged and discharged.

In the arrangement shown as an exemplary embodiment, the capacitor 33 is from a direct current source 34, 35 is charged via an impedance 36 shown as a resistor and discharged via a circuit that has the discharge path 32 and a self-induction 37 contains. Either the capacitance 33 or the resistor 36 or both can be set up variably to the To be able to change the frequency of the voltage generated by the inverter. That Grid 38 of the discharge path 32 is via the secondary winding 39 of a transformer 40 connected to a sliding contact 41 of a voltage divider 42. The voltage divider is connected at 43 and 44 to the current source 34, 35, that is, connected in parallel to the charging circuit of the capacitor 33. The primary winding 45 of the transformer 40 is via a phase setting serving branch consisting of a capacitor 46 and a resistor 47 the power source ι ο via the lines 48, 19 and 49, 20 "connected.

The cathodes and grids of the discharge paths 31 are connected via lines 51, 52, 53 and 54 and the switch 50 and further to the secondary winding 55 of the transformer 56 connected to the conversion circuit (inverter). The connections to the conversion circuit are connected to the sliding contact of the voltage divider 42 and at 58 between the resistor 36 and capacitor 33 are made, although other connections are made can be selected, through which a periodic voltage, the amplitude of which is greater than the grid bias of the discharge paths 31, can be taken from the inverter. The primary winding 59 of the transformer 56 is via lines 48, 19 and 49 ', 20 with the power source 10 connected.

The grid circles of each of the discharge paths 2, ji and 32 are provided with protective resistors 60 (current limiting resistors). The cathodes of these discharge paths are protected by switches 61, which represent time switches and are only closed after the cathodes are sufficiently heated.

The mode of operation of the arrangement is as follows:

The switches 61 are closed and the switch 50 is in its lower position Position. Let us also assume the time instant in which the voltage source 34, 35 is applied to the conversion circuit (inverter). The voltage across the capacitor 33 is then zero; the full voltage of the power source is therefore applied to the resistor 36. The potential of terminal 58 of the capacitor is therefore the same as that of connection 34 of the power source. As a result of the setting of the sliding contact 41 on the voltage divider 42, the grid 38 of the discharge path 32 is negative with respect to the cathode 62, which is connected to the terminal 58. The one over the grid in addition AC voltage supplied to transformer 40 is less negative than the voltage across resistor 36. Capacitor 33 charges, and point 58 becomes more and more negative, until finally that Grid 38 is positive with respect to the cathode 62 and, as a result, the discharge path 32 becomes current-permeable and thereby discharges the capacitor 33 again. By the Presence of self-induction 37 or the (distributed) self-induction of the discharge circuit the voltage of the discharge path 32 is momentarily reversed, so that the current flow through the discharge path is interrupted until the mentioned Process repeated.

The periodic voltage applied to resistor 36 in the charging circuit of the Capacitor 33 occurs, the grid of the discharge paths is pressed in counteraction with a bias voltage resulting from the voltage of the transformer 56 and one from the setting of the sliding contact 57 at the voltage divider 42 is composed of certain voltage. The periodic

The voltage across the resistor 36 has a greater amplitude than the voltage composed of the voltage supplied by the transformer 56 and the voltage supplied by the voltage divider 42. When the switch 50 is in the lower position and the capacitor 33 is uncharged, the cathodes of the discharge paths 31 are positive with respect to their grid and the discharge paths 31 are therefore blocked. When capacitor 33 charges, a point is reached where the bias voltage composed of the voltage from voltage divider 42 and the voltage from transformer 56 becomes greater than the voltage across resistor 36, in other words, the voltage at that point 58. The discharge paths 31 are therefore current-permeable. The main discharge paths 2 then also become current-permeable, and the current in the welding circuit is increased by the decrease in the impedance of this circuit. After the discharge path 32 has discharged the capacitor 33, the discharge paths 31 are blocked again by their bias voltage, and as a result of the interruption of the current flow through these discharge paths and their circuits, the current flow through the main discharge paths 2 and their circuits is blocked, thereby increasing the impedance of the welding circuit which reduces the current flowing in this circuit.
The course of the above-mentioned control voltages is shown graphically in Fig. 2. Therein, the bias of the grid 38 of the discharge path 32 is shown by the curve α, which results from the alternating voltage from the transformer 40 and

of the voltage b supplied by the voltage divider 42 via the contact 41. The voltage at the resistor 36 is represented by the curve c from the instant in which the voltage source 34, 35 is connected to the inverter circuit up to the instant in which the discharge path 32 becomes current-permeable at the point d . The voltage 34, 35 is assumed to be 250 volts, so that the maximum voltage at the point 58, which occurs when the power source is switched on to the inverter circuit, is consequently also 250 volts. If the potential of the point 58 and thus that of the cathode 62 becomes smaller than that of the grid 38, which has a bias voltage α, the discharge path 32 ignites at d, and the potential of the grid 38 increases to a value e, which as a result the presence of the impedance in the discharge circuit of the discharge path 32 exceeds the amount of 250 volts. The potential of the point 58 or the cathode 62 then falls according to a curve f which intersects the curve g at h and the curve α at i . The curve g represents the bias voltage of the grid of the discharge paths 31 and comprises the alternating voltage from the transformer 56 and a bias voltage / which corresponds to the setting of the sliding contact 57 on the voltage divider 42. When the voltage across the resistor 36 becomes smaller than the bias voltage supplied to the discharge paths 31, these discharge paths become live, and current now flows in a discharge path up to point k. When using high vacuum discharge paths, the flow of current is practically interrupted at /. The flow of current through the discharge paths 31 is initiated again at h ', and the process described is then repeated.

It should be noted that the alternating voltage supplied by the conversion circuit (inverter) must have a period which is a multiple of the period of the supply current source. In the case of the special embodiment shown, the period is exactly three times as long. It should also be emphasized that the current is initiated and interrupted at prescribed, predetermined parts of the period of the supply current source 10. By shifting or adjusting the phase position of the grid voltages of the discharge paths 31 and 32 (with the aid of the transformer 40 and 56), it is possible to set the time at which the current flow increases (starts) and at which it decreases (stops). , because this setting shifts the curves α and g relative to one another in the direction of the time axis. It is not absolutely necessary to use a transformer 56; However, the use of such a device is advantageous, since the periodic voltage applied to the grids of the discharge paths 31 causes the arrangement to work more precisely and the wave peaks of the bias voltage cause small voltage fluctuations in the control circuit, which can result from the use of discharge paths with slightly different characteristics, render harmless. The differences in the characteristics of the discharge paths can be due to small differences in the manufacture of the discharge paths or to the age of the discharge paths.

The period of the voltage generated by the conversion circuit (inverter) is determined by the choice of impedance 36 and capacitance 33. The amplitude of these Tension is determined by tension

of the current source 34, 35 and the value of the impedance 37 in the discharge circuit. In In the illustrated specific embodiment, the arrangement is when placed down Switch set to short blocking time and long switch-on time. By flipping the Switch 50 in its upper position occurs. The reverse occurs; the arrangement then works preferably with short switch-on times and long blocking times.

Fig. 3 shows an embodiment of the invention for the case of resistance spot welding. The arrangement serves to be able to set or control the duration of the supply of the welding current and even being able to use times that are only part of a period of the supply current turn off. In this case, a switch actuated by a cam wheel, for example, is known in the art Way used to trigger the control circuit of discharge paths. The duration of the flow of the welding current becomes controlled and mastered at all times by the electrical circuit of the discharge paths. The welding current only starts again when the switch is opened and then closed again has been.

The control circuit to be used for spot welding machines according to Fig. 3 is in essentially the same as that shown in Fig. 1, with the difference that the inverter circuit has been modified somewhat to allow for the generation of individual current and voltage surges to enable. For the corresponding parts of Figs. 1 and 3 are the the same reference numerals are used in both figures.

In the arrangement according to FIG. 3, the connection 44 of the charging circuit of the inverter is made in a central point of the voltage divider 42, which is connected to the current source 34, 35. The grid 38 of the discharge path 32 receives a negative voltage via the sliding contact 41, the resistor 70 and the line 71. A negative voltage is applied to the grid via the connection 72, the lines 73, 74, the discharge path 75 and lines 76, 77 when the discharge gap 75 is current-permeable. This discharge path is also one with an arc-like discharge. Its grid 78 is connected via a current limiting resistor 60, the line 79, the secondary winding of the grid transformer 80 and the line 81 to the negative pole 35 of the current source, which is led to the voltage divider 42. As a result of this switching, the grid of the discharge path 75, when no voltage is being transmitted through the transformer 80, is negative with respect to the cathode, and the discharge path is therefore blocked. The grid transformer 80 is located in the discharge circuit of the capacitor 33 ¹ . As a result of the voltage surge that occurs in the grid transformer when the discharge current flows, the discharge gap 75 becomes current-permeable.

Due to its form of discharge, this discharge path can only be removed again by removing it their anode voltage are blocked. This is with the help of a switch 82 and a capacitor 83 causes. The desk

82 is the above-mentioned switch actuated by, for example, a cam. While closing of switch 82 becomes the capacitor

83 connected to the discharge path 75. This capacitor 83 has previously been charged by the current source 34, 35 via the line 84, the resistor 85, the lines 77 and 71, the resistor 70 and the contact 41 on the voltage divider 42. By closing the switch 82, the positively charged plate of the capacitor 83 is connected to the cathode of the discharge path 75 and the negatively charged plate of the capacitor is connected to the anode of the discharge path 75, so that this is negative with respect to the cathode until the capacitor is over the resistor 70 has discharged. This discharge time is selected to be so long that deionization can take place in the discharge path 75 and the control grid regains its blocking effect. When the discharge path 75 is blocked, the anode thereof becomes positive again until the capacitor 83 has been charged in the opposite direction via the resistor 70 to a voltage which is determined by the setting of the sliding contact 41. The discharge gap 75 can therefore be made current-permeable in or in the vicinity of the peak of the next positive half-wave.

As stated above, the bias on the discharge gap 32 is when the discharge gap 75 is not permeable to current due to the setting (position) of the sliding contact 41 determined. If the discharge path 75 is current-permeable, the pre- voltage of the discharge path 32 by the voltage drop across the resistor 70 as a result the current through the discharge gap 75 is greater; d. H. the bias is around that Voltage between point 72 and the i * 5 Sliding contact 41 of the voltage divider 42 is larger when you consider the voltage drops in the circle between this point 72 and the grid is neglected. The setting of the Sliding contact is chosen so that when the discharge path 75 is not energized is that in the grid 38 of the discharge path 32

The voltage supplied by the transformer 40 is just sufficient to cover the discharge path to be energized near the top of the voltage curve. If, however the discharge path 75 is live, then the voltage at the grid 38 is the discharge path 32 always sufficiently negative to keep it locked. The circuit is therefore blocked when

ίο when the discharge path 75 is current-permeable is and the sliding contact 57 is in such a setting that the Lattice of the discharge paths 31 are sufficiently negative to block this discharge

«5 maneuvering routes to effect.

The switch 82 is closed after the welding electrodes 5, 5 are pressurized have been. Closing this switch causes the discharge path to commutate 75 with the aid of the capacitor 83, as described. This allows the preload of the discharge path 32 to "the voltage resulting from the setting of the Sliding contact 41 results, are reduced. This is due to the grid transformer 40 transmitted alternating voltage small enough to carry this current To be able to effect discharge path. As a result of the current carrying of the discharge path 32 discharges the capacitor 33. This "causes the discharge paths 31 become live, the polarity of the grid voltages of the discharge paths 2 reverses and these become current-permeable and consequently in the above-described Way current can flow to the welding transformer. The capacitor 33 is over the resistor 36 is charged again, and the discharge paths 31 are blocked again. As a result, the discharge paths 2 are made current-permeable, as a result of which the reduction of the current flow in the welding circuit is effected. The grid transformer 80 is located in the discharge circuit of capacitor 33 and transfers a temporary voltage to the grid 78 of the discharge path 75, as a result of which this discharge path is made live and transfers the higher negative bias voltage to the discharge gap 32 so that this cannot become energized again, although switch 82 remains closed. After this the switch is open, the capacitor 83 recharges, and the arrangement is ready to respond again.

For a better understanding of the described mode of operation, Fig. 4 is used, in which the mentioned high voltages are shown graphically. As zero voltage, i.e., the voltage referred to is the voltage at point 44.

The voltage at the sliding contact 41 is represented by mi and the voltage at the terminal 72 by η . The voltage of the grid transformer 40 is superimposed on these voltages. Starting from ο, the grid voltage of the discharge path 32 follows the solid curve up to point p, at which the voltage immediately drops to the value q as a result of the closing of the switch 82 and the effect of the capacitance 83. As a result of the extinction of the discharge gap 75, the bias voltage becomes lower, and approximately at r , the discharge gap 32 becomes live. When it becomes conductive as a result of the voltage impressed on its grid by the transformer 80, the discharge path moves, so to speak, the connection from the sliding contact 41 to the terminal 72 and gives the grid of the discharge path 32 a voltage j (as it was originally given to the grid) which is sufficiently negative in order to make these discharge gaps current impermeable. After the capacitor 33 has discharged through the discharge path 32, the capacitor 33 is charged again and generates a temporary voltage across the resistor 36, which is given to the control elements of the discharge paths 31, which have an opposite bias voltage g , which is made up of a direct voltage j and a composed by the grid transformer 56 superimposed alternating voltage. The discharge paths 31 are made current-permeable at h and current- impermeable at i.

If the circuit is interrupted via the discharge path 75 and 76, for example the conversion circuit (inverter) works in the same way as shown in Fig. 3 like the one according to Fig. 1, and the arrangement shown in Fig. 3 can therefore also be used can be used for seam welds according to Fig. 1. The connections between the lines 52, 53 and the grids and cathodes of the discharge paths 31 can controlled or switched by a switch such as the switch 50 indicated in FIG will. Furthermore, the phase position of the grid circles of the discharge paths 31 and 32 with the help of the transformers 40 and 56 supplied voltages set in the desired manner by suitable circuits used for phase shifting will. Such adjustability has been discussed above in connection with the arrangement described according to Fig. 1. A capacitor 86, which is connected in parallel to the secondary winding of the grid transformer 80, serves to flatten the peaks of the voltage, which arise when the capacitor 33 discharges; it also serves to

Discharge range 75 works to perfect.

In the arrangements described in more detail above, the use of Discharge paths with arc-like discharge and zero characteristic assumed. Such discharge paths are current- 'permeable when their grid voltage in relation on its cathode assumes the value zero. Instead, arc-like or arc-like discharge paths can be used Discharge with positive or negative grid characteristic can be used.

Claims (4)

Patent claims: i. Device to electrical point or Spot welding using controlled steam or gas discharge paths, whose control electrodes are supplied with voltage surges while avoiding mechanical switches, such as that, once or in a rhythmic sequence, welding currents of a duration greater or less than that of a half-wave the AC supply voltage, flow, characterized in that the primary side (17) a transformer (15) for the control electrodes of the discharge paths lies in a bridge, one branch of which consists of a resistor (24) and part of one to the AC supply voltage connected voltage divider (18), the other branch of which from the other part of the voltage divider and the primary winding (26) of a secondary side transformer that can be short-circuited through grid-controlled auxiliary discharge paths (27) exists, so that the phase of the Control voltage can be rotated by almost i8o °. 2. Device according to claim 1, characterized in that the control electrodes control voltages are supplied to the discharge paths via the secondary circuit of the transformer of the phase shifter are composed of an alternating voltage, of a changeable voltage DC voltage and a voltage applied to the series resistor of a relaxation circuit is produced. 3. Device according to claim 2, characterized in that for unloading the capacitor of the relaxation circuit is a grid-controlled auxiliary discharge path (32) is provided with steam or gas filling, the grid of which a control voltage is supplied, which in its phase position with respect to the AC supply voltage of the welding circuit is adjustable. 4. Device according to claim 2 and 3 for spot welding, characterized in that that in the grid circle of the auxiliary discharge path (32) another grid-controlled Vapor- or gas-filled auxiliary discharge path (75) is located, which is part of a likewise- in the grid circle of the first Auxiliary discharge path lying potentiometer can short-circuit, so that in the If the grid of the first auxiliary discharge path (32) is conducting, a blocking direct voltage is supplied to it, and by operating a switch (82) through a charged capacitor (83) is deleted, the short-circuit of the part of the potentiometer and thereby the first auxiliary discharge path releases, whereupon their reignition by a current pulse of the first auxiliary discharge path via a transformer in the grid circle of the second auxiliary discharge path. 1 sheet of drawings