DE636314C - DC generator for constant current - Google Patents

Description

When short-circuiting an ordinary DC machine with shunt self-excitation occur shortly before the complete extinction of the current, as is well known, very large currents, since the excitation field as a result of the The retarding effect of the eddy currents in the massive iron of the pole cores only slowly decays. Such a machine is therefore for a use with operational short circuits, such as for example occur in arc welding, can only be used to a limited extent.

It is now known to apply a counter-magnetizing main current winding to the main poles in order to avoid the current surges that occur during the transition to another load state to limit. The effect of the counter-magnetizing main current winding must, however, be canceled when the steady state has occurred will. According to the invention, this is achieved in that the main poles in addition to the usual shunt excitation winding carry two counteracting main current windings connected in parallel, whose circuits have different self-induction, namely the circuit has that main current winding, which magnetizes in the sense of the shunt excitation winding, a much higher self-induction than the circuit of the other main current winding opposing the shunt winding.

As such, the two opposing main current windings are of concern Number of turns and ohmic 3f> resistance dimensioned to be approximately the same. In the event of a short circuit, the winding that is used in the sense of the shunt excitation winding magnetized, made ineffective, for example by a choke coil permanently connected in series with it. This choke coil has the effect that the rapidly increasing current in the event of short circuits is largely only the other, relatively Induction-free main current winding flows through, 'causing an immediate weakening of the main field occurs.

Although it is known to have fast-regulating effects through various sizing of the To achieve inductance of excitation windings connected in parallel. Such an arrangement However, up to now it has only been used for separately excited field windings of direct current generators in which the direct interaction between the operating circuit and the excitation circuit does not exist is.

Several exemplary embodiments of the invention are shown in the drawing. Fig. Ι schematically shows a two-pole DC generator A with series-connected shunt exciting windings B _1, B ₂ and parallel-connected main current coils C _1, C ₂ - The coil _C1 is connected in series with an ohmic resistance D in series, while the winding C ₂ a throttle E is connected upstream. The other terminals of the parallel connected windings are C ₁ , C ₂

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connected by a second resistor F to which the outgoing line is connected at a suitable point. This arrangement has the advantage that by. Moving the connection point on the resistor i ⁷ the effect of the two series windings C ₁ , C _{2 can be changed} in their ratio "to each other in a very simple way,
ίο This is an advantageous coordination of the dynamic characteristics of the new DC generator z. B. achieved for different ■ operating currents. However, this tuning does not have to be done by the resistor F. The same effect, namely the change in the ratio of the self-induction to the ohmic resistance of a main current exciter circuit relative to the same ratio of the other circuit, can also take place within the meaning of the invention by other means known per se, for example by connecting or disconnecting turns of one or both main current exciter windings.

The means for achieving the static current-voltage falling characteristic of the constant current generator are not shown in Fig. ι for the sake of clarity. They can be of a known type or they can correspond to the arrangements described below.

In addition to the previously described influencing • the dynamic characteristics, according to of the invention on the new direct current generator in a simple manner a particularly suitable one for the present purpose The static characteristics can be influenced. This further refinement the invention consists in that one in the parallel main current exciter windings introduces an electromotive force in the area of the turning zone from the commutator is tapped. In two-pole machines, for example, this can be done in such a way that the brushes are divided and are pushed apart a little and between part brushes that belong together The removed voltage is introduced into the parallel main current exciter circuits. This comes across the main current windings an equalizing current comes about, because the part brushes in the area of the turning zone stand, is essentially dependent on the reversing pole flux. The equalizing current is superimposed the mains current, with a suitable connection in the magnetizing winding in the same direction and in the opposite direction in the counter-magnetizing winding, so that it is in both Has a magnetizing effect on the windings. For reasons of symmetry both brushes of a two-pole machine are expediently subdivided in the manner described and accordingly the two Hauptstrpmwicklungen also divided into two halves, so that 'Each subdivided brush has a part wick - "'. Iffllgspaar in the parallel circuit characteristic of the present invention is. Each of these partial winding pairs can normally be on one Main pole be attached, or the main poles can be divided tangentially or axially so that each partial pole carries one of the partial windings described.

In the case of four-pole or multi-pole machines, the arrangement described is particularly simple. The brushes do not need to be divided, but rather homopolar brushes shifted against each other, so that a tension occurs between them, which in the parallel main circuits is introduced. By this combination of against each other displaced brushes with the parallel main current windings the advantage is achieved that without additional means only with the main current exciter windings according to the invention both favorable dynamic and suitable static characteristics can be brought about.

This type of brush displacement is known per se; but it is for someone else Purpose has been proposed, namely to give a machine the property at supply voltage with the same sign in each direction of rotation. Applying this Type of brush displacement in connection with the series windings connected in parallel On the other hand, constant current machines are produced on the main poles, the static characteristics of which are very well suited to welding operations and similar establishments are adapted. It should also be noted that also to achieve a current-voltage characteristic curve favorable for arc welding has been proposed is to move the main brushes out of the neutral position; but for this purpose all brushes were in the shifted the same circumferential direction.

In order to explain this further embodiment of the invention in more detail with reference to the drawing, the basic circuit of a conventional four-pole DC machine is illustrated in FIG. 2. In order to, that a four-pole arrangement is used as a basis, however, should not be expressed, that, especially for larger powers, multi-pole machines are not an option can.

The brushes G ₁ , G ₂ and H ₁ , H ₂ are shifted from the zero position in the sense mentioned. The main current windings _{C 1} and C _{2 of the PoIeJT 1} and K _{2 are} connected between the brushes G ₁ and G _2. The outer one

Current is taken in the middle L _{1 of} the connecting cable and leads to a main terminal M of the machine. On the side of the branch point Cinen L ₁ is according to the invention, the throttle E _1, on the other hand optionally a resistance D _1, to compensate for the effective resistance of the throttle. Similarly, between the brushes H ₁ and H _{2 are} the turns C ₃ and

ίο C ₄ of PoIeJl ₃ and K ₄ switched. A line leads from the middle point L ₂ to the second outer terminal N of the machine. On one side of the branch point L ₂ there is again a throttle E ₂ , on the other side possibly a resistor D ₂ .

In the arrangement shown, the associated main current windings C ₁ and C ₂ or C ₃ and C _{4 are} accommodated on different poles. It could be on

ao two associated main current windings C ₁ and C ₂ are arranged for each pole, but the effect would be less strong than with the arrangement on separate poles, the fields of which are independent of one another.

In addition to the windings mentioned, the main poles also have an ordinary shunt winding. In the line leading from the branch point L ₂ to the main terminal N , the reversible pole main current winding O is switched on, for example. Parallel to the reversing pole winding is a shunt P to which the shunt winding A ₁ , R ₂ , R ₃ and 7-4 of the main poles are connected at a suitable point. On the other hand, these windings are placed on the other pole M of the machine. It has been shown that it is particularly useful to connect the turns of two related poles in series and these two groups in parallel. In many cases it can also be advantageous to connect a small choke in the circuit of the shunt at point Q in order to avoid polarity reversal with certainty.

The shunt P to the reversing pole winding O, from which the excitation current for the main poles K, which is proportional to the terminal voltage, is taken, has the effect as if an additional magnetization proportional to the terminal voltage was present on the reversing poles. But you can also connect the excitation winding R to a suitable tap of the reversing pole winding O itself, but the shunt P, even if it is not absolutely necessary, can still be retained in certain cases, since experience has shown that it has a beneficial effect by being at Changes in current weakens the influence of the reversing pole winding on the main magnetization to the advantage of the dynamic characteristics.

It is also possible, as indicated in FIG. 3, to carry out the circuit in such a way that instead of the shunt P for the actual reversing-pole winding O, an additional reversing-pole winding S is arranged, which is connected to the main terminals M and N of the machine.

With the aid of the arrangement according to the invention, the machine receives characteristics with regard to the dependence of the terminal voltage V on the external current I , as shown in FIG. 4.

To set the desired amperage during welding, it is best to change the magnetic resistance of the reversing pole circles in a manner known per se. Fig. 5 shows one possible embodiment. One or more iron pins U are pushed more or less deep into one or more bores T of the reversible pole core from the back. If all the bores of the reversing pole core are filled with iron, the magnetic resistance of the reversing pole circles is the smallest and the current intensity is greatest.

Fig. 6 shows the arrangement according to the invention in a two-pole power generator, in which the main poles and the commutator brushes are each divided into two parts.

Claims (15)

Patent claims: 1. DC generator for constant current with shunt excitation winding and two opposing main current _{windings, characterized in that the two main current windings (C 1} , C ₂ ) are connected in parallel and the circuit of that main current winding (C ₂ ), which in the sense of the shunt excitation winding (B ₂ ) magnetized, has a higher self-induction than the circuit of the oppositely magnetizing main current winding (C ₁ ). 2. DC generator according to claim i, characterized in that the main current winding (C ₂ ) magnetized in the same direction as the shunt winding is preceded by a choke (Is), while the other (C ₁ ) can be preceded by an ohmic resistor (£>). 3. DC generator according to claim i, characterized in that the additional main current windings (C ₁ , C ₂ ) are dimensioned equally. 4. DC generator according to claim i, characterized in that the ratio of self-induction to the ohmic resistance of the two main Current excitation circuits relative to each other for the purpose of setting the dynamic Characteristic curves of the generator can be changed with means known per se. S direct current generator according to claim 4, characterized in that the two main current windings (C ₁ and C ₂ ) connected in parallel are connected to a common ohmic resistor (F) in such a way that the portion of the two parallel branches in the ohmic resistor (F) can be changed. 6. DC generator according to claim ι to 5 with reversing poles, characterized in that in two-pole machines, the poles for the purpose of subdividing the two parallel main current excitation windings (C ₁ , C ₂ ) and generating a compensating current directed through them in the tangential or axial direction and divided Brushes "are also divided so that of two associated partial poles (K ₁ , K ₂ or K ₃ , K ₄ ) one has a counter-magnetizing winding (C ₁ or C ₄ ), the circuit of which has lower self-induction, and the other partial pole carries a magnetizing winding (C ₂ or C ₃ ) whose circuit has higher self-induction, and that each end of the partial windings (C ₁ to C ₄ ) lead to the outer circuit and the other two ends to partial brushes (G ₁ , G ₂ and H ₁ , H ₂ ) are performed in such a way that the other ends of the windings (C ₁ , C ₂ and C ₃ , C ₄ ) are connected to matching partial brushes with approximately the same potential (Fig. 6). 7. DC generator according to claim ι to 5 with commutating poles, characterized in that when four or more pole machines the mutually parallel-connected main current excitation coils (C _1, C ₂₎ are divided into coil groups (C _1, C ₂ or C _3, C ₄₎ are in such a way that of every two adjacent poles provided with the windings of a winding group, one has a counter-magnetizing winding (C ₁ or C ₄ ), the circuit of which has low self-induction, and the other a magnetizing winding (C ₂ or C ₃ ) whose circuit has increased self-induction, so that these partial windings (C ₁ , C ₂ or C ₃ , C ₄ ) on one side via chokes (E ₁ , E ₂ ) and possibly via ohmic resistances (D ₁ , IJ ₂ ) are connected to the main machine terminals (M, N) , and that Go turns the other ends of the windings of each winding group (C ₁ , C ₂ or C ₃ , C ₄ ) into brushes (G ₁ , G ₂ or U ₁ , H ₂ ) approximately the same potential are carried out for the purpose of Er generation of a compensating current superimposed on the operating current in the windings (C ₁ to C ₄ ) are shifted against each other (Fig. 2). 8. DC generator according to claim 6, characterized in that the shunt excitation coils (R ₁ , R ₂ or R ₃ , R ₄ ) of two adjacent poles are connected in series and these groups are connected in parallel. 9. DC generator according to claim 6 to 8, characterized in that that the reversing poles are dependent on the terminal voltage for the purpose of influencing the static characteristics of the generator additional excitation are provided. 10. DC generator according to claim 9, characterized in that the reversing poles apart from the usual series winding (O) have a special shunt winding (S) (Fig. 3). 11. DC generator according to claim 9, characterized in that the series winding (O) of the reversing poles has a shunt (P) at which the excitation current for the shunt excitation (R) of the main poles is removed at a suitable point (Fig. 2). 12. DC generator according to claim 11, characterized in that in the shunt circuit (P) of the reversing pole winding (O) switched on a choke coil is. 13. DC generator according to claim 9, characterized in that the Series winding (O) of the reversing poles ioo taps to decrease the shunt excitation current who owns the main pole. 14. Device for regulating the armature current strength of the direct current generator according to claim 1 to 13, characterized in that the regulation by . Change in the magnetic resistance of the turning poie takes place. 15. Device for regulating the armature current strength of the direct current generator according to claim 14, characterized in that the regulation of the magnetic Resistance of the reversing poles takes place by changing their active iron cross-section (Fig. 5). 1 sheet of drawings