DE1178960B - DC welding generator - Google Patents

Description

DC welding generator for electrical welding works one often with direct current. It is customary to use this from the available alternating current of the network by using a rotating transformer that consists of an asynchronous motor and a high-intensity low-voltage dynamo: Such transformer arrangements are heavy and inconvenient. In particular are collector and brushes are a very extensive part of the dynamo. Your making is expensive; they must be carefully maintained by a professional.

It is known that in an alternator the passage a DC component through the AC windings to an impact which tends to stop the alternator from being energized and thus the tension is significantly reduced. This appearance makes itself special noticeable in homopolar alternators. One applies for the rectifier the arrangement that allows the passage of direct current through the alternating current windings avoids, there arises another disadvantage in that two rectifiers the phase must be excited and therefore the structural scope compared to the classic arrangement doubled. The invention is based on known direct current welding generators at. It is seen in a combination of components that are independent in themselves are known from each other and for which individually and in partial combination no protection is coveted.

It has also already been proposed for AC welding machines that the current by means of a single-phase alternator of increased frequency produce. This generator consists of a rotating induction device with permanent magnets and a rigid inductor with a number of independent coils for in-phase Currents. A selectable number of coils can then be selected using a suitable commutator connect in parallel to close the welding circuit. Such a single phase alternator however, it is unsuitable for direct current welding in practice, which in general is preferred to welding with alternating current.

As is well known, the direct current generated by rectifying a Monophase current is obtained, much too high oscillations than that for the Majority of uses would be suitable.

The new DC welding generator is made by a combination of the the following components known as such: a) an alternator conventional, unpolarized design with one polarized by magnets Metal fittings formed inductor; b) windings on this alternator, each a multi-phase circuit, preferably a four-phase star circuit form with zero point; c) Silicon dry rectifiers, each in series in a phase of the multiphase circle are arranged in such a way that between the rectifiers and the zero point of the polyphase circuit are a direct current circuit trains.

According to the invention is also advantageous that the alternating current generator forms multiphase circles from polarized shaped metal pieces with magnets, which are preferably shifted against the phase, such that each circuit has its own phase rectifier and contains a special zero point. In cooperation with this, switches are provided, to connect a useful variable of this multiphase to the terminals of the welding circuit Selectable circuits to be switched on.

With this new overall arrangement, the passage of the direct current component do not lead to significant disadvantages due to the alternating current windings, because in the usual unpolarized alternating current generator used is capable of such Component does not smooth the magnetic flux, since this is between -i- 0 and - 0 fluctuates. Furthermore, the modern magnets generally have a very high Reluctance on; which prevents the formation of noticeable parasitic currents. aside from that it is not necessary due to the excitation caused by the permanent magnets, from the little men take an excitation current from the direct current circuit, which would result in unacceptable disadvantages. After all, it enables the invention to apply a single rectifier per phase, where it is not it is necessary to use a double number of rectifiers.

The new generator is improved according to the invention in that he several windings of a four-phase star connection with neutral point and silicon diodes contains in each phase. The corresponding direct current poles are connected to the power control connected to the neutral points of a selectable winding network. Is beneficial according to the invention that the alternator has different windings for two contains opposite phases with neutral point; also that the neutral points of all windings are permanently connected to the corresponding pole of the DC circuit and for regulation on two diodes, the ends of an optional number of windings are connected.

The invention is shown in the drawing in exemplary embodiments shown, which apart from the features also the advantages of the basic design and their further developments.

F i g. Fig. 1 shows an embodiment of an alternator according to the invention with diodes and regulation by impedance coils: F i g. 2 corresponds to an embodiment in which the power of the generator is regulated by a commutator; F i G. 3 and 4 show two types of another embodiment with an alternator, which contains many windings optionally connected to a single pair of diodes are.

In the embodiment according to FIG. 1 the alternating current is supplied by a permanent magnet alternator driven by a suitable motor. This generator carries four groups of windings 10, 11, 12, 13. The windings of each group are connected in parallel. Each group corresponds to one phase of a four-phase circuit. Each of the phases formed in this way is connected on the one hand to a silicon diode 8 and on the other hand to a neutral point 9. The outlets of all diodes are connected to one and the same terminal 7. The return connection between each phase and the neutral point has been made by means of simple, controllable impedance coils 14 a, 14 b, 15 a, 15 b , whereby the two simple self-inductors that belong to two opposite phases are designed in the form of a single coil, which sits on a single adjustable core. Well understood, this circuit must be designed in such a way that the control of the crane also influences the two halves of the double self-induction which is produced in this way; z. B. the two windings 14 a, 14 b or 15a, 15 b can be arranged one above the other. The possibility thus arises of generating an alternating current of medium frequency, which, as is known, reduces the fluctuations in the smoothed direct current, e.g. B. frequencies between 150 and 450 hz can be selected.

In the circuit according to FIG. 2, each winding of the alternator is double and feeds two diodes. Each of the windings under consideration is connected to another in such a way that a four-phase basic circuit is realized, e.g. B. the double winding 16a, 16b feeds the two diodes 8, the outlets of which finally end at the common terminal 7. The center point of this winding is connected to the center point of another double winding 17a, 17b, which feeds the two diodes 8, which are also connected to terminal 7. It will be understood that when the two double windings 16a, 17b are connected in quadrature, the overall circuit forms a four-phase system. A perfectly usable direct current is obtained between the terminal 7 and the connection 18 , which is the common return current of the two double windings.

The above explanations, which have been given with regard to the two double windings 16a, 16b as well as 17a and 17b, also apply to all other double windings of the alternator, e.g. B. for the double windings of the alternator, e.g. B. for the double windings 19 a, 19 b and 20a, 20 b with the common point 21, etc. The common points 18, 21 , etc. end at the successive blocks 22, 23, etc. of a multi-way switch 24, which has an extended, movable contact 25 has. This allows a selectable number of fixed blocks to be connected in parallel and to be connected to terminal 9 , which forms the second terminal of the direct current line. In this way you can connect a different number of double winding pairs of the alternator and therefore regulate the output of this alternator. The successive pairs of windings, such as 16a, 16b, 17a, 17b, may or may not be in phase with respect to one another; in the latter case, a first four-phase arrangement 16 a, 16 b, 17a, 17b can be superimposed on a second corresponding arrangement 19 a, 19 b, 20 a, 20 b, which second arrangement with respect to the first by a phase angle z. B. is offset by 90 °. However, other offsets such as 22 °, 30 'or 30 ° or 45 ° can also be used for the phase shift, to name just a few examples. Depending on how the number of blocks that are connected in parallel by the multi-way switch 24 is increased, the number of specific phases that contribute to supplying the circuit with direct current is also increased. Correspondingly, the irregularity of the direct current is reduced to the same extent.

In Fig. 3 shows two successive pairs of windings 31 and 32 of the alternator: this can contain any number of such windings. Each of these groups comprises two members 31 a and 31 b or 32 a and 32 b, which correspond to the two opposite phases.

In other words, these phases are offset from one another by 180 °. The inner ends of the two basic windings 31 a and 31 b or 32 a and 32 b, ie the winding ends that would normally be connected to one another to form the neutral point, end in connections 31 e and 31 d or 32 c and 32 d, respectively. These belong to two separate switches 31 e and 32 e. With the aid of the latter, the connections 31 c, 31 d, 32 c, 32 d can be connected to the same conductor 33 which ends at the positive pole 9 of the direct current circuit. The outer ends of the basic windings of each group 31 and 32 are connected to two conductors 34 a and 34 b, respectively. These end in two diodes 8 a and 8 b, the opposite poles of which are connected in parallel to the negative terminal of the direct current.

When the switches 31 e and 32 e are open, apparently no flows Current between the terminals 9 and 7. When the switch 31 e is closed, for example is, then current flows from the winding 31 on the one hand via the line 33 and on the other hand via conductors 34a and 34b. The direct current circuit branched off between terminals 9 and 7 is therefore traversed by a rectified current, which is a direct current welding secures in an appropriate manner. When switch 32e is closed, the winding group becomes 32 effective, so that the power at the connections 9 and 7 is doubled. It will be understood that the other sets of windings used by the alternator Feeding can contribute, as do groups 31 and 32, the influence that has just been described. All of these groups can take effect one after the other, when the alternator is used at full power.

To avoid circulating current between the different winding groups, it is advantageous that all of these groups have the same phase, however this is not critical, because if the alternator has sufficient self-induction possesses, the circulating currents can only remain within an acceptable size. In addition, it is always possible to shield them more or less completely by self-impedance coils at the appropriate points on the conductors 33, 34 a and 34 b arranges.

In the arrangement of FIGS. 4, the inner points of the basic windings 31 a, 31 b and 32 a, 32 b are connected to one another. In this way, a common point is created which is permanently located on the conductor 33 by means of a data 31 f or 32 f. The outer ends of these basic windings then end in the connections 31 c, 31 d and 32 c, 32 d of the switches 31e and 32e. The other connections of these switches end in conductors 34 a and 34 b.

It can be understood that when the switches 31e and 32e are opened are, the two winding groups 31 and 32 do not emit any current. Consequently will the DC circuit is not energized. If you turn the switch 31 e the Group 31 closes, so group 31 secures the supply of the diodes and delivers in the direct current circuit all the power of which it (group 31) is capable.

This performance can be increased by choosing as well the group 32 and the other winding groups sequentially turns on which the alternator contains each.

Claims (4)

Claims: 1. DC welding generator, d a d u r c h marked, that it consists of a combination of the following components known as such: a) an alternator of conventional, unpole type with a through Magnets inductor formed from polarized metal fittings; b) windings (10, 11, 12, 13) on this alternator, each with a multi-phase circuit, preferably form a circle in a four-phase star connection with zero point (9); c) Silicon dry rectifiers (8), each in series in one phase of the polyphase Circle are arranged in such a way that between the rectifiers and the Zero point of the multi-phase circuit forms a direct current circuit. 2. DC welding generator according to claim 1, characterized by an alternating current generator with magnets made of polarized metal fittings, which forms several multiphase circles (16 a, 16 b, 17 a, 17 b) , which are preferably phase-shifted from one another, each circuit has its own phase rectifier (8 ) and contains a special zero point (18) and switches (22, 25) are provided in order to selectively connect a number of variables of these multi-phase circuits to the terminals (7, 9) of the welding circuit. 3. direct current welding generator according to claim 1, characterized in that the alternating current generator with magnets made of polarized metal fittings several two-phase circles (31a, 31b) in F i g. 4 has two phases offset by 180 °, which are permanently connected to two phase circles common silicon rectifiers (8a, 8b) and double contacts (31e) for connecting a number of variables of these circles to the common zero point (33). 4. DC welding generator according to claim 1, characterized by an alternating current generator with magnets made of polarized metal fittings, which has several two-phase circles (31 a, 31 b) with two phases offset by 180 °, which are permanently at the common zero point (33) and double contacts are arranged to connect a number of variables of these circles in parallel to silicon dry rectifiers (8 a, 8 b) . Documents considered: German Patent No. 529 008; German Auslegeschrift No. 1035 819; U.S. Patent Nos. 2,425,183, 2,626,367, 2,752,529; Welding Journal, October 1959, pp. 1014 and 10 1 5.