DE703909C - Electric power transmission, especially for diesel-electric vehicles - Google Patents

Description

The invention aims at electrical power transmissions, in particular those for diesel-electric vehicles, the changes in load fluctuations Speed or the voltage of the generator of the power transmission to a minimum reduce without the need for external regulating or control devices with moving parts are. A well-known way that leads to this goal is that the generator and possibly also the motors of the Power transmission as weakly saturated, i.e. oversized machines will. This enables the generator to operate even with very small changes in speed largely change its voltage and adjust the current consumption of the motors, so that it is driving Combustion engine practically approximates despite a change in the load conditions the same speed and power can be maintained. Due to the weakly saturated execution, of the electric motors of the power transmission, the extent of the voltage change in the event of load fluctuations can also be determined reduce, which indirectly limits the speed fluctuations further is brought about in the generator. The more abundant the oversizing of the machines, the closer one approaches the constancy of the speed of the generator and thus that of the internal combustion engine.

The object is achieved by the invention without such oversizing the machine is necessary by means of the excitation system of the generator or the motors or both arranged, without external control

establishment of current- or voltage-dependent resistors of certain properties and solved in a certain circuit. According to the invention, resistances are used with or with increasing or under load when the direction of current is reversed, the resistance value changes and is sufficiently smaller thermal time constant. They are parallel to an excitation winding or to an auxiliary power source so arranged in the excitation system, possibly connected to further resistors and dimensioned so that the Ampere turns in the excitation winding increase more strongly with increasing voltage than in the ratio of the voltage increase.

Suitable resistors with. when the resistance value increases, z. B. Resistors with a strongly variable temperature coefficient, such as the well- known iron wire resistors or the like with a small thermal time constant. They are preferably connected directly in parallel with the excitation windings of the generator or the motors and are therefore particularly suitable for influencing the excitation windings in series or compound motors in the main circuit. The voltage range of the generator feeding the motors can be effectively narrowed due to the automatic amplification of the motor field in the case of high loads and its automatic weakening in the case of small loads. In the case of excitation windings in a shunt or separate excitation circuit, J5 must be connected upstream of these and a common series resistor to the parallel resistor, if the supply lines cannot replace such a series resistor with their own resistor. An embodiment of this type with current or voltage-dependent resistors parallel to the shunt winding of the generator and to the series winding of the motor is explained below with reference to FIGS. 1 and 2 of the drawing. Also suitable as resistors with a resistance value that increases with load are electric valves that do not allow a further increase in the current flowing through them above a limit value (saturation current) from a certain voltage on. Resistors with increasing resistance value under load have already been proposed per se for the automatic control of excitation currents, z. B. to compensate for load changes caused by temperature fluctuations or to compensate for voltage fluctuations when the speed of the generator changes. In the known forms of application, however, they are not suitable for reducing the speed or voltage fluctuations of a generator running essentially at a constant speed because of their different dimensioning or switching. For example, they are designed to compensate for temperature influences as a thermal image of the excitation winding with a large thermal time constant, whereas the resistors according to the invention must have relatively small thermal time constants so that they easily follow the fluctuations to be compensated.

The invention makes no use of resistances with decreasing load Resistance value. Such have not yet become known in a form suitable for the purposes of the invention. The glow lamps already proposed for similar circuits have the disadvantage for the purpose of the invention that they only small currents lead to their ignition voltage being higher than the burning voltage and that they take on the properties of an arc gap when overloaded. Also the known uranium dioxide resistors can only be carried out economically for small outputs will. A common disadvantage of all types of resistors is that the resistance value decreases with load in that they can only be used to control excitation circuits in circuits in which the excitation circuit is proportionate large energy-consuming series resistors have to be inserted. For regulating main circuits, especially 9S They are therefore particularly unsuitable for influencing series motors.

Resistors with a resistance value that changes when the direction of current is reversed all valve cells that are at all with Span- '<«· voltage reversal exhibit non-linear current-voltage behavior by changing the current Oppose a slight resistance in one direction, in the event of voltage reversal but increase their resistance by leaps and bounds. Such valve cells can in particular with Advantageously used when a battery or other auxiliary power sources are used for excitation can also be used. They are expediently the in the self-exciter no circuit of the generator or the motors switched on auxiliary power source connected in parallel, they can also be supplemented by further resistors or valves to form a bridge circuit. You lock in Depending on the voltage changes in the excitation circuit, the current flow through the auxiliary power source or release it in one direction or the other. The bridge circuit can be designed in such a way that the iao current- or voltage-dependent resistors only in part of the operational

Load area parallel to the auxiliary power source and in a different part of the load area work in series. Such an exemplary embodiment is described below with reference to FIGS. 3 and 4.

In FIG. 1 of the drawing, 1 denotes the internal combustion engine of a diesel-electric power transmission, 2 denotes the generator driven by the latter and which feeds the electric motor 3. 4 is the shunt exciter winding of the generator, 5 ^{eme the} main current exciter winding (composite or counter-composite winding) of the same. 6 is the series excitation winding of the motor 3. The shunt winding 4 of the generator is the iron wire resistor 7, and the series excitation winding 6 of the motor is the iron wire resistor 8 connected in parallel. An ordinary ohmic resistor 9 is also connected in series with the bypass winding of the generator.

The effect of the iron wire resistance in the excitation system of the generator is shown in FIG. Is α, the current-voltage characteristic of the entire excitation circuit, b that of the iron wire resistor 7, a current voltage characteristic is obtained in the field winding 4 according to the characteristic c, the ib by subtracting the current in the iron wire resistance from the total current i is obtained.

As shown in FIG. 2, with the curved current- voltage characteristic curve c, it is possible to largely reduce the speed changes of the generator when the voltage changes, even in machines operating in the saturation region. If the characteristics% to% represent machine characteristics corresponding to different speeds and it is assumed that a voltage change from C ₁ to e _{2 is} necessary in the generator, then with a straight current voltage curve in the excitation winding, as shown in the figure by the dashed line d , an increase in the speed of the generator from Ti ₁ to% is necessary, since the straight running characteristic curve d at voltage e ₂ already intersects with the characteristic curve% (intersection point P). By contrast, the curved current- voltage characteristic curve c of the exciter winding allows the same voltage increase of the generator to be achieved even with a much smaller change in speed. As the drawing shows, the characteristic curve c intersects the machine characteristic curve n ₂ (intersection point Q) at the level of the voltage e _2, which corresponds to a significantly lower increase in speed. By appropriately designing the resistors , one is able to conform the current-voltage characteristic of the excitation winding largely to the course of the machine characteristic, so that flat sections are obtained without having to work in the straight, unsaturated part of the machine characteristic as before.

The parallel connection of the iron wire resistor to the series excitation winding 6 of the motor means that from a certain size of the current, if the current falls further, the current in the excitation winding decreases more than linearly, because the proportion of the current through the iron wire resistance increases. this has As a result, the motors have essentially the same behavior as weakly saturated ones Machines, since the linear drop in the current in the excitation winding has a similar effect as the linear current drop in the unsaturated machine.

Such an effect can also be achieved in the generator in that the Series winding 5 of the same a resistor with a strongly temperature-dependent behavior is connected in parallel. Through this you get an increased effect of the series winding in the area of high ' Currents. In order to save a further iron wire resistor, the arrangement can also be made so that "one and the same Iron wire resistance to the series windings connected with one another the generator and the motor are connected in parallel together.

An embodiment with valve cells is shown in Fig. 3, which shows only the generator 2 of the power transmission with its excitation system. A battery 10 is connected to the excitation circuit by means of a bridge circuit, in one diagonal of which the battery itself lies, in whose other diagonal the shunt excitation winding 4 of the generator is located. Two opposite branches of the bridge are formed by the valves 11, 12, the other two branches by ordinary ohmic resistances

When the generator voltage is zero, the battery feeds the field winding via the circuit a, b, c, d, e, f. If the generator itself begins to supply voltage, this is added to the battery voltage. The excitation runs according to the beam I shown in FIG. 4, the slope of which is given 115 by the resistors 13, 14 in the excitation circuit. If, at a certain generator voltage (points in FIG. 4), the voltage drop in resistor 13 is greater than the battery voltage, then valve 11 is flowed through and thus the battery is switched off. The excitation current now flows through a, b, d, e, f. The corresponding excitation beam

Claims (8)

is designated in Fig. 4 with II. If the generator voltage continues to rise, the voltage drop in resistor 14 also becomes equal to the battery voltage (point /? In FIG. 4); if the voltage continues to rise, current flows through valve 12. The excitation current now flows through a, b, d, c, e, f, the battery voltage counteracts the generator voltage. This results in exciter beam III in FIG. 4. In this case, a similar current voltage line OABD can be achieved for the excitation system as the characteristic c according to FIG even with large voltage changes on the generator, only small fluctuations in speed of the generator are caused. By appropriate choice of the resistors 13 and 14, both the position of the points Λ and B, and the inclination of the beams I, II, III can be changed as required. In order for the battery voltage to come into its own, it must have a certain size compared to the generator voltage (about V _{4 of} the generator voltage). If only a significantly lower battery voltage is available, the generator can be designed with a neutral conductor connection and the excitation can be connected to the neutral conductor and one outer conductor, i.e. the generator can be excited with about half the terminal voltage. Is it enough. To work with only two excitation beams I, II or II. IJI, one or the other part of the bridge can be omitted. In one case the result is a circuit in which the battery is in series with the resistor 13 and parallel to the valve 11, in the other case the battery is in series with the valve 12 in parallel with the resistor 14. If the drive motors are designed as compound machines, the above described circuit can also be applied to them. Likewise with this Circuit also additional resistors with non-linear characteristics in parallel or in Row with the shunt winding can be arranged, whereby instead of the straight excitation rays I, II, III correspondingly curved lines can be obtained. Godfather νϊ claims: ι. Electric power transmission, in particular for diesel-electric vehicles, consisting of a generator driven at essentially constant speed and one or more drive motors running at variable speed, characterized in that one or more current- or voltage-dependent resistors with increasing under load or motors parallel with current reversal changing resistance value and sufficiently small thermal time constant to a field winding or to an auxiliary power source in the excitation system of the generator or the Mo _# or both arranged such ge optionally connected to other resistors and sized are that the ampere turns in the excitation winding increase more strongly with increasing voltage than in the ratio of the voltage increase. 2. Power transmission according to claim 1, characterized in that the excitation windings of the generator or the Mo-. gates resistors with a highly variable positive temperature coefficient (Iron wire resistors or the like) and small thermal time constant connected in parallel are. 3. Power transmission according to claim 1 or 2, characterized in that the current- or voltage-dependent resistors in parallel with a series winding or co-connected winding of the motor or motors are connected. 4. Power transmission according to claim 1, wherein a battery or other auxiliary power source is used to excite the generator or motor, characterized in that the im Self-excitation circuit of the machine switched on auxiliary power source dependent on the current direction Resistors or electrical valves are connected in parallel, which are also through further resistors or Valves can be added to a bridge circuit and depending on the Voltage changes in the excitation circuit reduce the current flow through the auxiliary power source increase or weaken or release in one direction or the other, so that the excitation current in the higher tensions rises more sharply than the lower tensions. 5. Power transmission according to claim 4, characterized in that the current or voltage-dependent resistors and the auxiliary power source to a bridge circuit are connected, by means of which the resistances only in a part -des lx-instinctual load range for Auxiliary power source in parallel, in another part of the load area with her work in series. 6. Power transmission according to claim 4 or S, characterized in that in the excitation circuit of the generator switched on a battery by means of a bridge circuit is, in whose one diagonal the battery, in whose other diagonal the excitation winding is, while two opposite sides of the bridge circuit of current direction-dependent resistors, preferably electrical Valves, the other two opposite sides of ordinary ohms Resistors are formed. 7. Power transmission according to claim 4, 5 or 6, characterized in that the generator is designed with a neutral connection and its self-excitation is connected between the neutral conductor and an outer conductor. 8. Power transmission according to claim 4 so to 7, characterized in that the excitation windings have further resistors with a non-linear current-voltage characteristic are connected in parallel or in series to provide an additional curvature of the excitation characteristic to obtain. 1 sheet of drawings BERLIN .. GKDMlC-KT IN Ilfcli! ¹ KIi