DE156616C - - Google Patents

Description

IMPERIAL

PATENT OFFICE.

PATENT LETTERING

M 156616 CLASS 21 d.

JEAN LUCIEN FARNY in ZURICH. DC machine.

Patented in the German Empire on April 10, 1903. Longest duration: September 27, 1916.

The present invention relates to a substantial improvement of that disclosed in the German patent specification 139823, class 21 d, described DC machine.

The correct commutation (transfer of the Current conduction from the windings to be detached to the detached) 1. from the electrical Resistance of the armature windings, ίο 2. the speed of the machine,

3. Dependent on the size of the tension of the machine, and depending on the size of the The current intensity delivered at the moment is to find out an appropriate brush position.

The present invention remedies all of these inconveniences, i. H. it the following is achieved: 1. that the brush position can be kept unchanged from idling up to full load, 2. that the commutation as soon as a critical speed is exceeded, is independent of the speed of the machine, 3. that the commutation is due to the internal resistance the machine becomes independent, and

4. that the commutation is independent of the magnitude of the voltage.

This goal is achieved in that one during the parallel connection in the an appropriate additional electromotive force against the winding to be switched off the current strength in that winding and, at the same time, in the winding that replaces it, but can act in the same sense with the current strength to be developed in it.

These additional electromotive forces are by means of a special additional Magnet system generated, for example 1. in the windings of an armature, which of the anchor, which is described in patent specification 139823, class 21 d, is arranged separately is. Here, of course, one winding of the first armature must be combined with the corresponding one of the second armature can be connected in series. However, 2. the arrangement can be made in this way that this particular magnet system acts directly on the windings of that armature, this armature of course is to be expanded in such a way that it just comes into the area of the additional special magnet system; 3. is it possible keep the anchor used in patent 139823 without modification if the additional magnet system in the

written is built into it in such a way that it is nonetheless used as a magnet system with from the first independent magnetic circuit is preserved.

The invention will now be explained with reference to the drawings.

Fig. Ι shows the time course of the electromotive force of a winding, such as those of the patent specification 139823, class 2id, is based. From time 2 (Fig. 1) This electromotive force is constant up to time 7 and from time 9 to 14. Let it be called the main electromotive force.

Fig. 2 shows the time course of the additional electromotive force of the same This electromotive force may be commutation electromotive force to be named. The shape of the wave or the pulse 2, 3, 4 (Fig. 2) can be arbitrary be. There are, for example, two rectified consecutive pulses produced that there are two magnetic fields of the same name on each other on the armature circumference can follow, which are included in the spool span.

The interval 4 to 5 (Fig. 2) in which between the two consecutive opposite impulses no electromotive force occurs, is thereby produced that between the north and south poles of the additional magnet system following one another on the armature circumference arranges a correspondingly elongated neutral zone. With an arrangement of the same polarity would make the gap between the prongs long enough. Fig. 3 shows the from the electromotive forces of FIGS. 1 and 2 resulting course of the total electromotive Power of the same winding.

In Fig. 3 is the resulting curve for the use of the machine as a DC generator intended.

If one would reverse the impulses in Fig. 2 and then the total electromotive Forming the force of the winding, one would get the curve shape Fig. 4. One becomes from the The following can be seen without further ado that in the event that the main electromotive Force acts in the opposite direction, then the commutation electromotive force also acts to create the current in the winding as long as it is detaching to cause and, when it is then to be replaced, to disappear again bring. Fig. 4 thus represents the shape of the total electromotive force as they do would have to be designed when using the machine as an electric motor.

The implementation of the total electromotive force (according to FIG. 3 or 4) can take place, for example, according to the diagram in FIG. 5. In this, A, B and C represent three consecutive coils. JV and S are the magnetic fields which generate the main electromotive forces in these three coils as soon as the coils move relative to them. EF represents the excitation coil of the fields JV and S. η s ii t are the magnetic fields that generate the commutation electromotive forces in the same coils ABG , ef represents the excitation coil of the fields nsnt.

It must be ensured for example by arrangement of a magnetically inert space between the magnetic circuits JV S and η s ensure that neither the excitation coil the pole EF nor the exciter coil ef inversely the poles JV S to magnetize able ns.

One can also see the influences of the which are incompatible with the process in the machine Avoid one magnet system on the other by removing any magnetizable Intermediate pieces, which would allow an impermissible magnetic flow from one system into the other, surrounds by auxiliary excitation coils and sends an electric current through them, which is so dimensioned that as a result of the magnetomotive force generated by it the magnetic Flow in those intermediate pieces is canceled.

However, one could also arrange coils which are only in the area of the fields JV and S and those which would only come under the influence of the fields nsut and which switch the former coils one behind the other with the second. In this way, the commutation electromotive force can be generated in a different number of turns than the main electromotive force. In the arrangement according to FIG. 6, the main and commutation electromotive force are generated at the same armature circumference. A centric-symmetrical sequence of fields can also be achieved here.

Here again it must be ensured that the poles η s etc. would not be excited in the slightest, for example, by exciting the poles JV and S or, conversely, the poles JV S etc. by exciting the poles η s at the same time as the process in the Machine would be aroused in an incompatible manner. For this purpose, either the yoke parts connecting the main poles in opposite polarity are separated by radially running, magnetically indifferent layers from those yoke parts which connect the auxiliary poles lying between the main poles, or the auxiliary poles arranged between two main poles of opposite polarity are provided.

pole yokes, which are closed in themselves parallel to that which is common to all main poles Main yoke run, but separated from the latter by a magnetically indifferent layer are.

Instead of this aid, the magnetically indifferent layer can be both on arrange the poles of the additional system as auxiliary excitation coils on the main poles,

ίο in which currents of such direction and Size to be sent through, that the incompatible with the process in the machine, field strengths generated by the influence of one system in the other be canceled.

For example, FIG. 7 shows an arrangement in which the fields of the commutation electromotive forces have been shifted into those of the main electromotive forces. Here one can also see from FIG. 8 how the magnetic circuits H and / of the commutation pole fields independently through the magnetic coils e, g, f and k. can be excited and run in the pole yoke of the main poles.

There must be the commutation pulses in two consecutive windings at the same time occur and have opposite directions.

9 thus shows the temporal relationship of the total electromotive forces of consecutive windings.

In -den Fig. 5, 6 and 7 represent the right. Corner XY and ZV schematically represent those contact parts of the current extraction device which are mechanically connected to the fields. In Fig. 6 there are still two contact parts QP and KL , because two periods elapse until the coils come back into the position shown, ax, c \, by, d ν etc., on the other hand, represent those contact parts which are electrically connected to the winding are connected. The contact parts XY, ZV etc. are in electrical connection with slip rings m and Z, for example when the fields are movable and the armature windings are stationary. Conversely, if the armature windings are made movable, these contact parts XY, ZV etc. can be made in two parts instead of α x, c \ etc. and connected directly to the terminals of the machine.

The machine works as follows:

The winding AB etc. (Figs. 5, 6 and 7) should be thought of as resting. If one proceeds from the idea that in Fig. 9 the instantaneous values of the electromotive forces have been plotted in each case where the boundary line YV (Fig. 5 and 7) was currently located, one can easily see due to the assumed mutual position of the Fig. 9, 5 and 7, that is produced by the current extraction device, the winding A, in which the electromotive force 1-2-3 ■ ¹ · S (Fig. 9) connected to the network at the time 2 (Figure 9 ·.) and is separated from the same at time 7 when the contact parts XY, ZV move from left to right, - The winding B, in which the electromotive force 16-5-17-7-18-19-20-21-12-22 (FIG. 9) is switched to the mains at time 5, whereby it remains parallel to winding A until time 7 (FIG. 9). At time 7, A is disconnected from the network, and up to time 18, B remains in connection with the network alone. At this point in time 18, a further winding C, in which the electromotive force 24-18-25-20-26-27 (FIG. 9) is developed, is connected to the network in parallel with winding B.

So the different windings are sequentially carrying the current of the Ankers have to take over after they have switched on the electricity for a while had led jointly with the winding to be detached. As you can see it is The process is largely the same as that described in patent 139823, cl. 2id. Only the transition of the current from one winding to the next is taken care of here in a different, more perfect way than there, by means of the commutation electromotive forces. While there the current in the alternating winding in proportion to the increase in the main electromotive Force in the same and the decrease in the main electromotive force in the winding to be switched off increased, and furthermore the current in the winding to be detached decreased in the same proportion as which increased in the detaching winding, this increase and decrease in the main electromotive force can be disregarded here. Only the commutation electromotive forces are to be dimensioned in such a way that the transition of the current from the winding to be detached to the winding to be detached complete cancellation of the current in the process to be replaced.

The sense of the commutation pulses is of course always to be chosen so that under Its influence is increased by the current in the winding to be removed and, at the same time, in the winding to be removed Winding decreases. The two commutation pulses cannot influence the network because they are in their Effect against this (because equal and opposite) cancel out. It shows up at mathematical investigation of the size of the commutation pulse that the same

times the amplitude of the current to be commutated, i.e. proportional to the external current must be to get correct commutation. So the useful electricity or a part of it is used to generate it the magnetic commutation fields. When the machine is idling So there is no electromotive force of the commutation, and the successive one and switching off the windings, in which then only electromotive forces are involved occur the course according to Fig. ι, causes a constant running open circuit voltage on the terminals.

You can of course arrange the machine in question with multiple poles. It is then possible to connect the coils that are the same in each pole pair field permanently in parallel or in series before they are connected to the contact parts α χ, by , etc. If, however, this permanent connection of the coils is omitted, then on the other hand one sees without further ado that, provided that contact parts of the type XY and ZV have also been arranged in each pole pair field, constant potential differences must occur at these. By connecting the contact parts of this type to one another accordingly, it is possible to connect these constant potential differences in series or in parallel.

Claims (4)

Patent-to sayings: i. DC generator and motor according to patent 139823, class 2id, characterized in that that the transition of the current lead from the to be detached to the detached windings by additional electromotive force impulses are caused in these windings themselves (or in special with them in Series connected windings) during their parallel connection "by means of one of the main poles independently excited magnet system are generated so that at the same time an impulse in a winding to be detached against the one flowing in it Current and one such in a detaching winding in the sense of that to be developed in it Stromes is directed. 2. Execution of the arrangement according to claim 1, characterized in that the excitation windings of the magnet system, which is excited independently of the main poles, in the armature circuit of the machine are switched and provided with an adjustable shunt resistor, so that the additional electromotive Force impulses increase and decrease with the external current and their size can be regulated. 3. Execution of the arrangement according to claim 1, characterized in that the magnet systems that generate the main and additional electromotive forces are built into each other in such a way that only one anchor body and only one magnet frame with two systems of independent magnetic circuits available. 4. Execution of the device according to claim 1 as a machine with several Main pole pairs and corresponding ones that generate additional electromotive forces Auxiliary pole pairs, characterized by such an arrangement of the correct Switching the armature windings causes devices that the constant potential difference generated under a pole pair field connected in series or in parallel with those that are generated in the adjacent pole pair fields will. 1 sheet of drawings.