DE718909C - Device for regulating systems for electrical resistance welding - Google Patents

Description

Device for regulating systems for electrical resistance welding The invention relates to electrical systems for resistance welding where the welding current corresponds to the various properties of the material to be welded must be adjusted. In the case of systems of the known type, the welding current .from a AC power source during, determined selected half-cycles of the alternating current delivered. In order to change the welding heat, the time at which the power is supplied is used changed in each of the half periods. The number of half cycles for each weld should be referred to as the time setting of the welding process; the setting of the ignition point, on the other hand, is called the heat control. The time and heat setting takes place by reverse parallel-connected discharge paths acting as valves, which allow an uninterrupted flow of current for a maximum of one half-cycle. The flow of current through the valves is initiated by impulses on the ignition electrode are given. The time setting is effected by the ignition pulses during given a certain number of consecutive half-periods. the Heat effect is regulated by the fact that the point in time, because in each half-period the ignition pulse becomes effective, is set accordingly. The phase angle at which the ignition pulses take effect is usually through an adjustable phase shift network e customary. Such a network consists of a pair of phase shifters Impedances, which are arranged in series with a power source, and from means, about that between a point on each of these impedances and one in between Tapping to tap potential. With the known institutions is a voltage divider in parallel with the amen series impedance network, and one the terminals of the phase shifter assembly is called the variable tap of the voltage divider used.

It has been found in such devices. that if the variable tap is shifted from point to point of the voltage divider, the welding current does not change evenly with the adjustment of the tap. For a considerable part of the available adjustment range, especially on both Ends of that, is the change in current flow at different tap settings -not important. Accordingly, only a relatively small part of the Voltage divider can be used for commercial purposes.

The aim of the invention is to make the current flow essentially as steady To train the function of the setting on the voltage divider. According to the invention the voltage divider is connected to the point of the phase shifter impedances that are between the ends of which lie and are selected in such a way that the current flows through the load as an essentially linear function of the setting on the voltage divider its whole area changes. Here the intermediate connection point is one of the phase shift impedances, to which the voltage divider is connected, selected so that it has a current value corresponds to such a small size that no noticeable effect on the electricity consumer occurs. The intermediate connection point of the other phase shifter impedance is chosen so that when the voltage divider is set to this point, the current flow at points in time of the voltage half-waves of the power source begins, which is essentially with the maximum current match that can flow through the power consumer, where the power factor is to be considered. Since there are welding loads, their phase shift changes over relatively very large areas is the latter Phase shift impedance according to a further invention with a number of intermediate connection points each of which corresponds to a different power factor.

An embodiment of the subject matter of the invention is shown in Fig. i, Fig. 2 is a graph showing the relationship between the setting the voltage divider and the load current in the known devices. Fig. 3 is a graph showing the relationship between the current and the settings of the voltage divider in a device according to the invention, and Fig. 4 gives the relationship between your power factor and the setting amounts one of the phase shifter impedances.

The device according to FIG. I contains a welding transformer 5, the secondary winding 7 of which supplies current to the weld metal 9 via a pair of electrodes II. The primary winding 13 is supplied from a current source 15 via discharge vessels 17 and 19, which are connected in parallel in the opposite direction. Each of these vessels has an anode 21, a mercury cathode 23 and an ignition electrode 25 made of boron carbide or a similar substance, which is immersed in the mercury. each one of the discharge paths carries a current surge for a half cycle.

This current surge in the discharge vessels occurs at predetermined times of the half-periods are initiated by sending pulses to the ignition electrode of the relevant Discharge distance are given. If this is ignited once during a half cycle the current continues to flow until a short time after the half-cycle has expired, where the length of current flow is determined by the power factor of the pantograph will. The number of half cycles during which the current flow is going on becomes determined by a magnetic pulse device 37 of known type. This selection is taken by the fact that the ignition pulses for the discharge vessels 17 and I9 over gas-filled discharge tubes 27 and 29 with anodes 31, cathodes 33 and control electrodes 35 run. These are controlled by their control electrodes during the selected half-periods 35 and cathodes 33 made impulses conductive. The pulse generator 37 contains a permanent magnetic iron core 39 with an air gap 41 -, over which a disk q.3 rotates synchronously with the power source 15. There are pins in the circumference of this disk 45 are used, which enter the air gap 41 during selected half-periods and induce voltage pulses in coils 47 and 49. These coils are in control loops 51 and 53 turned on, the timing tubes 27 and 29 in a known manner influence.

A second pair of discharge tubes 55 and 57 serve. as thermal regulators; they determine the points in time in the half-periods at which the main discharge vessels 17 and 19 are made conductive. Each of these tubes consists of an anode 59, a cathode 61 and a control electrode 63, which are arranged in a gas-filled vessel. One heat control device and one time limiter are connected in series with the ignition electrode of each of the main discharge vessels. The circuit for the vessel 17 runs from the main conductor 65 via a conductor 67, a current limiting resistor 69: the anode 59 and the cathode 61 of the tube 57, the conductors 71 and 73, the anode 31, the cathode 33 of the tube 27, one Conductor 75, the ignition electrode 2.5 of the vessel 17, the cathode 23, a conductor 77 and the primary winding 13 to the second main conductor 79 of the current source 15. The heat regulators 57 and 59 are influenced by a phase shifter network 81 via regulating transformers 83 and 85, respectively . The network consists of resistors 87 connected in parallel, which are connected in series with a choke coil 89 to the secondary winding 9 i of an auxiliary transformer 93. Instead of the resistors 87 and the inductive resistance 89 phase shift impedances of another type can be used; For example, instead of the resistor 89, a capacitance can be used.

The resistor arrangement 87 is provided with a connection point 95, while the throttle89 a plurality. such connection points 97 has. A Voltage divider 99 is between point 95 of resistor arrangement 87 and a the connection points 97 .des resistor 89 connected. The potential between the variable current decrease IoI at the voltage divider 99 and a center tap 103 of the secondary coil 9i of the auxiliary transformer 93 is the primary windings Io5 of the regulating transformers 83 and 8'5 pressed on. For this purpose are the changeable Connection IoI with the common connection point of one of the terminals of the primary windings Io5 and the center tap 103 of the transformer 93 with a point at one Equalizing resistor 107 connected to the other terminals of the primary windings Io5 is connected.

The setting points of the tap 101 on the voltage divider 99 correspond to different phase positions of the secondary windings. Io9 of the regulating transformers 83 and 85 of the impressed potential. The phase of this potentiometer changes over the entire voltage divider from an angle which corresponds to the intermediate connection point 95 of the resistor arrangement 87 to an angle which corresponds to the selected intermediate connection point 97 of the resistor 89. The secondary windings-1o9 of the transformers 83, 85 are connected to the control electrodes and the cathodes of the heat regulators 57 and -5-9, and the potential of these secondary windings is .deshy the corresponding control circuits iii and 113 pressed.

These potentials cause the thermostat to adjust , of the voltage divider 99 corresponding points of the half-waves become conductive. The pins 45 moved through the air gap in the iron core 39 generate potentials the time adjusters 27 and 29 during the selected half period leading, do. However, they become conductive at times in the half-cycle that are earlier lie as the earliest times at which the heat regulators 57 and 59 are conductive will. Correspondingly, resistors i 15 and 117 are connected in such a way that they are shunted to heat regulators 57 and 59 and so power paths for the timing devices form when these are conductive while the thermal regulators are not yet. the Resistors 115 and 117 are of such a size that the main discharge vessels 17 and i9 by the current flowing through the resistors and the ignition electrodes 25 cannot be made conductive.

If -the heat regulators 57 and 59 at the selected times of the Half-period are made conductive, current flows through the associated auxiliary electrodes a5, and the corresponding main discharge vessels 17 or. i9 are made conductive. The welding current is in this way for a predetermined number of half-periods, -which are determined by the arrangement of the pins 45 in the disc 43, and during the parts of the half-period; which is determined by the setting on the voltage divider 99 are flowing. By changing the variable tap IoI of the voltage divider 99 can be the points in the half-periods to which the discharge vessels 17 and i9 are conductive, are changed and thus also the delivery of the welding current-es. Of the Current decreases as the tap moves IoI from left to right and accordingly the welding current is a function of the setting thereof Tapping. In accordance with the invention, the intermediate connection points 95 and 97 the resistor assembly 87 and the choke coil 97 are selected so that the welding current a substantially linear function of the setting of the changeable port ioi and over the entire range of the voltage divider 99 is. If. Also the linearity the usually desired condition is there are cases; where the welding current is a function other than a linear function of the setting of the tap ioi. The invention should: also include these cases if the selection of connection points 95 and 97 is such that over the whole range of the voltage divider 99 there is an increase of the current is given for each subsequent adjustment.

When selecting the intermediate connection points 95 and 97, the Peculiarities of the facility are observed. Point 95 of the resistor arrangement 87 is chosen that when the variable tap IoI of the voltage divider 99 electrically coincides with it, the current sent into the weld metal 9 like this is low to produce any appreciable perspiration. The intermediate connection points 97 of the throttle 89 are chosen so that they are the .höchst possible current flow for the individual load levels correspond. The maximum current flows when .the discharge vessels 17 and I9 at angles in the half waves that correspond to the phase shift angles of the Load., Are conductive. So it must be the connection points 97 of the choke coil 89 ides correspond to the performance factors of the various loads.

The advantages of the invention can be seen from FIGS. In Fig. Z, the percentage of the maximum current is shown as a function of the setting on the voltage divider for the previously known devices. The result is that the useful range of the voltage divider, which the straight part II9 of the curve 1a1 shows and which extends approximately from the setting point z6 to the point 46, forms a relatively small part of the entire voltage divider. For a given length of the voltage divider, a considerable part of it is not used for any purposes and is therefore lost. , Fig. 3 shows the corresponding relationships in an arrangement according to the invention. The different curve lines 123, 125 and 127 correspond to the different power factors of 85, 55 and 25% entered in the figure. For the purpose of comparison, a straight lens 129 corresponding to the conditions according to the invention is shown, which runs adjacent to the points of the curves 123, 125 and 127. When comparing these curves with the line, it can be seen that, according to the invention, the current flow is an essential linear function of the setting. Accordingly, almost the entire range of the voltage divider can be used.

In practicing the invention, the phase shift factor of the power consumer 9 can be determined by any known manner, for example by using a power factor meter. The left end: the voltage divider 99 is then connected to a point 97 of the choke 89, the phase shift factor in question is equivalent to. The required tap can be taken from a curve 131, the in Fig. q. is shown, with the percentage of the length of the choke 89 as a function of the power factor is shown. In the execution described of the voltage divider 99 can have the variable tap IoI at one point of its Length can be adjusted to the desired current flow, with considerable accuracy since the whole range of the voltage divider is available for setting stands.

The voltage divider 99 is provided with a scale in the usual way, which is preferably evenly divided. By reading this scale, the operator can determine at once what percentage of the maximum current through the Weld metal flows to adjust the voltage divider accordingly. With the known Institutions, on the other hand, can only evaluate the displays on the scale to the extent that that a corresponding setting with some accuracy only applies to one Load with a selected power factor can be obtained. For from the selected factor different factors there is a substantial difference between the percentage of the maximum current to which the reading on the scale corresponds, and the really existing values. Because the various connection points 97 are provided on the choke coil 89, the various power factors this difference is avoided. When the voltage divider 99 with the Points 97 is connected, the existing phase shift factor of the Load, shows the! Scale exactly the percentage of the maximum current in the load.

Claims (3)

PATENT CLAIMS: i. Device for regulating systems for electrical Resistance welding, in which the electricity consumer is across in parallel and opposite switched discharge paths are fed, the ignition electrodes of which are and auxiliary discharge tubes for heat control by emanating from a pulse generator Voltage surges are controlled, one fed by the AC power source Network with a variable voltage divider the phase adjustment of the ignition timing determined, characterized in that the voltage divider (99) at points (95, 97) of the network (87, 89) is adjustable connected between its ends lie, whereby in one position there is no effect on the electricity consumer in the other an ignition point corresponding to the maximum current is achieved, such that when moving the moving Part of the voltage divider over its entire length the load current is practically a linear function of the setting is on the voltage divider. 2. Device according to claim i, characterized by that the connection point (97) of the. Voltage divider (99) at the impedance (89) of the Network (87, 89) is adjustable, with each connection point one of the different Corresponds to the power factors of the load circuit. 3. Device according to claim i or 2, characterized in that the transformer (93) feeding the network 07, 89) is adjustable at the center (Io3) of its secondary winding (9i) .with one in the circuit of the transformer (83, 85) for the control of the ignition point arranged resistor (107) is connected.