DE472809C - Regulation of direct current machines by means of a flow of freely flowing electrons depending on the speed - Google Patents

Description

Regulation of DC machines by means of a speed-dependent Flow of free flowing electrons It is known to drive DC motors on a required speed to keep that one by influencing a free Electran current in the excitation circuit, the excitation ampere turns of the DC motor changed in such a way that it eliminates any undesired speed change resulting from any cause automatically counterbalances. The effect of this arrangement is based on the exploitation a voltage following the speed fluctuations of the DC machine for influencing the flow of electrons through electric or magnetic fields. The same requirement can occur with DC machines whose speed is controlled by a command post can be controlled by means of a normal manual or remote-controlled controller. It will then requires any commanded speed from the DC machine among all Circumstances is complied with.

This uniqueness is now achieved through electrical and magnetic Processes in the DC machine called into question. In addition, with shunt regulation the voltage fluctuations, with voltage regulation the excitation fluctuations of the exciter ampere turns question the correct execution of the command, or inaccuracies in the transfer of the command from the command apparatus to the voltage regulator or the shunt regulation can produce the same undesirable effects.

According to the invention, all of these inaccuracies are to be eliminated will. Now, however, the controls with free electron streams can be regulated the direct current machine does not readily apply if the electron stream fed into it Influencing voltage as a fixed function of the speed of the DC machine to be controlled stands. The clear controllability of the motors can, however, be achieved by that the electrical or magnetic quantities of the command apparatus which determines the speed are automatically influenced in such a way that that the desired speeds can be achieved.

In Fig. I a DC motor i with the usual field winding is shown 2 thereby kept at a steady speed that the auxiliary exciter winding 3 through an electron tube.I experiences 6 stimuli as a function of the grid voltage, which let the machine i perform small oscillations around a medium speed. the Grid tension 6 is due to the tachometer dynamo 7 that came with the machine i is mechanically coupled.

Fig. 2 shows an example of the characteristics of the electron tube, ie the current intensity .T, in the excitation winding 3 as a function of the grid voltage E8. The relationships are assumed so that an average current intensity 1 corresponds to a voltage Es = o . The required speed must therefore correspond to a voltage in the grid circuit 6 with a value of o.

Fig. 3 shows the voltage E, the speedometer dynamo as a function on the speed n of the DC machine i. There is one in the grid circle Voltage source E12, which counteracts the tachometer dynamo voltage E7 in a known manner, so the machine i sets itself to the speed n ,. one, at the E, equal and opposite the voltage is E12. The resulting lattice circle voltage then has the Value o.

This speed 1i.1 would be that set on a command apparatus Speed correspond. The command apparatus 8 consists of a controller that controls the excitation current changed in the winding 2 of the machine i. If the command set 8 is now on a If the position corresponds to the speed, the voltage E12 be reduced to a value Eh n_, which of the speedometer dynamo 7 at of the speed n2 output voltage E, is equal and opposite. The rule system zag then automatically maintains the speed. The voltage E12 can e.g. B. be automatically controlled in that the controller 8 with a controller io is mechanically coupled, which changes the voltage E12 in the desired way.

If the speed of the DC machine i according to Fig. 4 remains constant Excitation by changing the voltage EB supplied to the brushes with the aid of a Command apparatus of a known type, e.g. B. a resistance regulator or an excitation current regulator controlled by a Leonard generator, the DC machine provides a speed required, which is proportional to this tension. Then the voltage of the speedometer dynamo E, connected in series with the voltage EB, then, as shown in Fig. 5 it can be seen, the additional voltage EB is regulated automatically in the same sense as the voltage E12 in Fig. 3, and it will have the same regulating effect as in the Fig.i scored. A correct adjustment of the voltage E, against the voltage EB can easily be done by a voltage divider i i, which is the place of the Command apparatus 8, io of Fig.

If the machine i is in Leonard circuit according to Fig. 6, d. H. will fed by the Leonard generator ig of the converter, the voltage corresponds EB does not exactly match the position of control lever 2o (command apparatus). This position but always clearly corresponds to the one at the terminals of the excitation winding 21 of the Leonard generator ig occurring voltage. If you switch this voltage with the voltage F__, the tour generator in opposition, like the voltage EB in Fig. q. you get one unambiguous control of the machine i by the command apparatus 2o under exclusion the internal inaccuracy effects of the Leonard converter ig and the DC machine i. The battery a2 in this figure is only used to heat the cathode q ..

Depending on the characteristics of the electron tubes used, it can be necessary, except for the voltage dependent on the speed and the opposite acting constant voltage source in the grid circuit a third constant voltage source to turn on. It is then possible to use the mean grid voltage independently of the Any positive or negative values of the two variable voltage sources To achieve values. For the ratio of the exciter ampere-turns of the windings 2 and 3 and thus for the speed and strength of the control stimuli applies to such Arrangements the same as for arrangements to maintain a steady Speed of non-controllable DC machines. Determining for the setting of this However, ampere turns is also the size of the inaccuracy in the present case the command transfer itself. Soft z. B. the speed of the DC machine i considerably depends on the speed required by the controller (command apparatus 2o), so the control circuit in which the electron tube is switched takes over the automatic one Correction of this difference. It is easy to see that one for certain load fluctuations sufficient control by such an inaccuracy transfer continues to be claimed, and it must be ensured that the recruitment The possibility given of the excitations is also sufficient for inaccuracies. E.g. must be shown in fig. q. the controller g to a smaller resistance value in the case of greater inaccuracy can be set. This increases the control stimuli in the winding 3 and are then able, in addition to the speed fluctuations due to load surges even the fluctuations caused by the inaccuracy in the command transmission balance.

The invention extends not only to DC machines as those, but also to arrangements where multiple machines are used and DC machines help maintain the speed, such as. B. Rule sets with DC rear machines, etc.

Claims (6)

PATENT CLAIMS: i. Regulation of DC machines by means of a speed-dependent flow of free-flowing electrons, characterized in that the size of the flow is simultaneously made dependent on the setting of the normal manual or remote-controlled speed controller used to regulate the DC motor. 2. Control arrangement according to claim i, characterized by an inevitable with the command apparatus (8) connected control element (io), which provides an additional counter voltage for speedometer dynamo regulates. 3. Control arrangement according to claim i, characterized in that that an additional voltage to the tachometer dynamo when regulating the speed by changing the voltage supplied to the brushes by connecting this voltage in series the speedometer dynamo is given. Control arrangement according to claim i, characterized by removing the additional voltage from the terminals of the excitation (2i) of one of the to regulating motor (i) driving Leonard generator (i9). 5. Control arrangement according to the claims 3 and q., characterized by a decrease in the additional voltage of one Voltage divider. 6. Control arrangement according to claims i to 5, characterized by Switching on a further additional voltage in the grid circle for the purpose of adaptation the voltage to the characteristics of the electron tube.