DE111123C - - Google Patents

Description

IMPERIAL

PATENT OFFICE.

PATENT LETTERING

CLASS 21: Electrical apparatus and machines.

EDWARD HIBBERD JOHNSON in NEW YORK.

with compound field winding.

Patented in the German Empire on May 26, 1899.

The present invention relates to methods and apparatus for regulating electric motors.

It is customary to use resistors in the armature circuits of motors, which ■ connected behind and next to each other to cause sudden changes in speed and To prevent sparking on the brushes and slide springs, and that is the case Resistors are particularly necessary when switching from series to side-by-side connections is effected. However, reservations must be made against all armature resistances, as they are for known causes adversely affect the running of the engine, and therefore the present invention seeks the goal of any external resistance that causes a drop in the potential at the anchor terminals causes to bring in failure and without damaging spark formation on the brushes of the line reverse current at all higher To feed speeds again.

The invention can be characterized in that it is applied to a low level Speeds practically working as a bypass machine according to its effect Motor consists of a single main current motor at the highest speeds transforms. It does this by arranging a multiple field winding, whose one works as a secondary winding, the other as a main current winding while using them at the same time a multiple armature winding, which is used to change the strength of the magnetic Field can be connected in a known manner in parallel or one behind the other, with the circuits of the electric motor are arranged in such a way that before a current change occurs from Series connection the speed of the motor as a result of the weakened Field is so increased that it equals the speed, which with a strong field is achieved after a change in side-by-side connection.

In the drawing, Fig. 1 is a blueprint of the circuit connections between the fixed ones Stromschlufsteile of a controller, a motor, which two armatures and two commutators with a field magnet Has composite winding, a collector battery arranged in two separate groups and the resistors used in connection with the field circuits of the motor come. Fig. 2 illustrates the power circuit pieces on the switching cylinder, whose design corresponds to the known of this type. Fig. 3 shows the power connection pieces on a reversing cylinder of known type, which is used to reverse the flow through the Field windings of the motor are used. Fig: 4 shows the various connections of the motor circuits, when the switching cylinder with its Stromschlufsstücke indicated in Fig. 2 over the fixed right-hand Stromschlufsstücke of Fig. 1 is rotated. It is in in this case it is assumed that the motor in connection with a divided collector battery, as indicated in Fig. 1, to continue

movement of electric vehicles or for similar purposes. Fig. 5 shows the various Circuit connections if one with two anchors and two commutators with a motor equipped with a field magnet with a composite winding in association with a other motor rich establishment for electric Tramways or railways are used; nine circuits are given here.

In Fig. Ι and 4, C ¹ and C ^{2 are} the commutators for the two armature windings of the motor. O is the shunt field winding and T is the winding for the main current field. R, R \ R ' ² and i? ³ are resistors, namely the first two in series with the secondary field winding or in short circuit, depending on what is required, the latter two in series to the poles of the main current field winding and partly in short circuit or unconnected, depending on the position of the regulator . The secondary field is only connected via a group of batteries for all positions of the controller, as shown in FIG.

The first position of the regulator or the speed no. 1 has the effect that the secondary field becomes unusually strong, with the resistor connected in series being short-circuited. The main current field is in the bypass to a weak resistance i? ³ , so that the ampere-turns are limited to the smallest amount of corn. The collector battery illustrated in FIG. ^{1 is} connected in two parallel rows B 1 B ' ^2. In this way you get with two commutators connected in series only 20 volts for each commutator, if z. .B. each battery group supplies 40 volts.

The second position of the regulator does not change the circuit connections from a practical point of view, only the secondary circuit field is weakened by the resistor R so that the motor is at least 50 pCt. is accelerated. The third position of the regulator brings the batteries from the secondary circuit into the series connection with 40 volts for each commutator, gives the secondary circuit field its maximum strength again and allows more current to go through the main current winding because the auxiliary resistor R- is in series with i? ^{3 is} switched on. This position gives the motor a 100 pCt. Increased speed compared to position 1. The fourth position runs the circuits in a practical way as in the previous position with the exception of the secondary field circuit, which is weakened by the resistors RR ¹ so that, if now more current through the one behind the other switched coils works, the whole field is so weak that the motor is reduced by at least 50 pCt. goes faster than with the previous knob position. In the fifth position of the controller, the armature circuits of the series in the parallel position are connected, and a large current passes through the connected one behind the other windings as a result thereof, that the resistors R 'and R ² are completely turned off. ³ The secondary loop field is of the same strength as in position 2 and the overall magnetization is approximately the same as in position 3. Each commutator receives in practical terms 80 volts, and the speed is therefore about 100 pCt. Larger than in position 3. The sixth and last position of the controller opens the secondary circuit completely, but leaves the other circuits as they were in the fifth position, causing the motor to accelerate and become an ordinary motor with a main current winding.

If the engine is to be used in conjunction with an electric vehicle, it gives The following can be seen from the above description of the circuits:

As the engine gradually evolves from a low-speed auxiliary engine to a Main current motor is converted to the highest speed, it turns out that the speed of the vehicle constant in practical terms at the lower speeds is, eanz indifferent what charge is present, but the highest speeds depend very much on the load. In other words, the engine will tilt at the slower speeds, Current through its armature windings in relation to the required torque to record. Excessive current will not cause sparks on the brushes, because in the first and second position of the regulator the voltage between each other following commutator bars is only a quarter of that at maximum speed.

Furthermore, the speed of the vehicle should be substantially that of a certain position speed corresponding to i, 2 or 3 of the controller exceed, for example as a result of descending travel, it follows that the motor automatically becomes a dynamo and recovers energy for the battery.

The vehicle should finally be running at top speed and the controller fast

O ~ O

are returned to position 2 or 1, it follows that a current flows through the Armature windings will go and charge the battery, but the same will be safer within Limits is kept because of the weakening effect of the main current field, which due to the weakening of the field strength

will correspondingly decrease the electromotive force of the armature. The charge of the The battery regulates itself automatically, i.e. a strong charging current weakens and reduces the field hence the 'electromotive force, and a weak charging current strengthens the field and increases it hence the electromotive force.

In Fig. 5, O 'denotes the shunt winding; C ¹ C ' ² are the commutators for the armature windings of one motor, O ² T' ² C ³ C ^{4 are} the corresponding windings and commutators of the other motor. Each armature circuit produces three different speeds as a result of a changed field strength.

The first three speed levels, numbers i, 2 and 3, give 125 full for each The commutator (at an operating voltage of 500 volts) and the motors work according to practical principles Terms as secondary engines due to the very strong secondary engine and of the weak main current field. Give the following three speeds, Nos. 4, 5 and 6 250 volts for each commutator. The main stream fields have now become considerably stronger as a result of an increase in the current through their windings, and the secondary fields are somewhat weakened by the introduction of one or more resistors in series. The last three speed levels, nos. 7, 8, g, give 500 volts for each commutator, with the loss coming from the main current winding is not calculated. The main current field at the seventh position is four times that stronger than in the first position, and in the eighth and ninth positions it is even wider increased as a result of more current going through the armature. The secondary field is a consequence so weakened by series connection with auxiliary resistors that the motors work as simple motors with main current winding at top speed. There in there is no external resistance to the armature windings, which is considerable Could cause a drop in potential, and because of the internal resistances of the motors themselves are comparatively low, it follows from this that the speed of the motors depends mainly on their counter electromotive forces, which in turn depends on the series-parallel connection of the armature windings and depend on the field strength. It It is also evident from the above description of the various circuit connections that the Motors no longer accelerate when the controller moves from the third to the fourth and from the sixth to the seventh position than between any two other positions (The speed in the third and sixth position is so due to the weakened Field increased so that it comes close to the speed at the fourth and seventh positions). The one shown in FIGS illustrated regulator with its Stromschlufsstücke is not claimed as an invention; its representation only pursues the purpose of showing the circuits.

Claims (1)

Patent claim: Method for changing the speed of one or more electric motors with compound field winding, characterized in that the field windings, one of which as shunt winding, the other as main current winding, with two or more armature circuits, which can be connected in parallel and one behind the other in a known manner, are combined, so that the motor as a result Change in the strength of the bypass or Main stream field through before respectively. parallel switched control resistances at low speeds according to its effect works practically as a secondary engine, at high speeds practically in one Main current motor passes over. For this purpose ι sheet of drawings.