RU2616111C1 - Method for regulating speed locomotive with electric transmission - Google Patents

Abstract

FIELD: electricity.

SUBSTANCE: method to control the speed of the locomotive with electric transmission is that emits a signal proportional to the actual speed, allocate a signal, which is proportional to the actual speed of the magnetic flux of the traction motor, calculate the movement resistance by the given values of the weight of the locomotive with the compound and profile of the movement area. According to the calculated value of the movement resistance and the known characteristics of the motor determine the setting of the traction current generator. Multiply the signal value proportional to the magnetic flux of the motor, with the magnitude of the setpoint speed, the obtained result is taken as the setpoint voltage of the generator. The acceleration of the locomotive is calculated, the calculated value is normalized and summed with a signal value, which is proportional to the actual speed. The result is compared with a predetermined value, the comparison result is integrated, by the result of the integration calculated set-point voltage of the generator is corrected and adjusted the voltage of the generator.

EFFECT: improved accuracy and speed of regulating the locomotive motion speed.

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Description

The invention relates to railway vehicles, in particular to the electrical equipment of electric vehicles, and relates to a method for controlling the speed of a locomotive, track machines.

A known method of controlling the speed of a locomotive with a train, in which the current value of the speed obtained by using the speed sensor, is compared with the set value in the comparison device, the difference is fed to the input of an amplifying device made in the form of a relay device, then the output signal of the relay device is fed to the input of the power control unit of the power plant (Automatic control systems for locomotives. M .: GOU "Educational and methodological center for education on the railway transport, ”2009, p. 398-418. Aut.: N.M. Lukov, A.P. Kosmodamiansky).

The disadvantage of the technical solution is that the relay principle of regulation causes a significant degree of oscillation of the processes in the power plant of the diesel locomotive, and accordingly the speed of the movement is also oscillatory, which makes it impossible to use the technical solution in the conditions of work of track equipment and in mountain work.

A known method of controlling the speed of a locomotive with electric transmission, adopted as a prototype, which consists in the fact that a signal proportional to the speed of movement is isolated, it is compared with a predetermined value and the voltage of the traction generator is changed, a signal proportional to the magnetic flux of the traction motor is isolated, a moment of time is fixed, when the difference in the magnitudes of the signals proportional to the actual and given speeds of movement becomes less than the predetermined value, the signal proportional to Beyond this difference, they integrate, calculate the resistance to movement according to the predetermined values of the weight of the locomotive with the composition and profile of the movement section, from the calculated value of the resistance to movement and the known characteristics of the traction motor determine the setpoint of the required current of the traction generator from the known value of the traction force of the locomotive, multiply the signal value, proportional to the magnetic flux of the traction motor, with the value of the set value of the speed of movement, the result is normalized, they are corrected by the magnitude of the voltage drop across the resistance of the traction electric motor circuits, the result of the adjustment is taken as the voltage setting of the traction generator, the set value of the required power of the traction generator is determined, for which the voltage value of the traction generator is multiplied with the current value of the traction generator, corrected by integrating the difference in the values of the signals proportional to actual and given speeds, the multiplication result is normalized and according to the obtained result reg liruyut power traction generator (patent RU №2551865 C1, IPC B60L 15 / 20,11 / 02, publ. May 27, 2015).

The disadvantage of the technical solution is that when working on diesel locomotives it is very difficult to determine with the required accuracy the actual weight of the train, the current track profile, and accordingly the resistance to movement, which leads to significant inaccuracies in determining the required current and power of the traction generator, and can to a large extent worsen dynamic performance when adjusting speed.

The technical result of the claimed invention is to improve the accuracy and speed of controlling the speed of the locomotive.

The technical result is achieved by the fact that in the method of controlling the speed of a locomotive with an electric transmission, which consists in emitting a signal proportional to the actual speed of the movement, isolating a signal proportional to the magnetic flux of the traction motor, calculating the resistance to movement according to the predetermined values of the weight of the locomotive with the composition and the profile of the movement section, the calculated value of the resistance to movement and the known characteristics of the traction motor determine the setpoint the current value of the traction generator according to the known value of the traction force of the locomotive, multiply the signal proportional to the magnetic flux of the traction motor with the value of the set value of the speed of travel, the result is taken as the voltage setting of the traction generator, the locomotive acceleration calculated by changing the actual speed in time is calculated the value is normalized and summed with the value of the signal proportional to the actual speed of movement, compare the result with data value, the comparison result is integrated, the integration is corrected by the result calculated by the traction alternator voltage setpoint and the result obtained is adjusted traction alternator voltage.

In FIG. 1 shows a block diagram of a device that implements the method, FIG. Figure 2 presents graphs characterizing the voltage on the traction motors of the locomotive U _dv as a function of the generator load current U _dv = f (I _g ) for a standing locomotive V = 0 (curve a ) and at a given speed V = V _s (curve b), and also the characteristic of the traction generator U _g = f (I _g ) at constant power for a certain value of the resistance to movement W (curve c).

The device (Fig. 1) consists of a speed sensor 1, an acceleration calculation unit 2, the input of which is connected to the output of the speed sensor 1, the output of the acceleration calculation unit 2 is connected to the first input of the adder 3, the second input of the adder 3 is connected to the output of the speed sensor 1, output the adder 3 is connected to the first input of the comparison unit 4, the second input of the comparison unit 4 is connected to the output of the speed adjuster 5, the output of the comparison unit 4 is connected to the input of the integrator 6, the output of the speed adjuster 5 is connected to the input of the motion resistance estimation unit 7, the output of which connected to the input of the traction generator current setpoint calculation unit 8, the output of the traction generator current setpoint calculation unit 8 is connected to the input of the functional converter 9, the output of which is connected to the first input of the multiplication unit 10, the second input of the multiplication unit 10 is connected to the output of the speed adjuster 5, output the multiplication unit 10 is connected to the first input of the adder 11, the second input of which is connected to the output of the integrator 6, the output of the adder 11 is connected to the input of the traction generator voltage control unit 12.

The method is as follows.

The speed sensor 1 (Fig. 1) emits a signal proportional to the actual speed, in block 2 the acceleration calculation determines the acceleration of the locomotive, normalize the obtained value, in adder 3 a value proportional to the acceleration, supplement the signal proportional to the actual speed V _f received the value in block 4 of comparison is compared with a given value of the speed of the locomotive V _s coming from the output of the master 5, which can be used as a regular controller of the driver or a remote control device (if necessary, remote control of the locomotive), the comparison result is integrated, for which it is output from the unit 4 of the comparison to the input of the integrator 6, in the unit 7 for assessing the resistance to movement at a given value of the speed of movement V _s , ahead of the set values of the weight of the locomotive (P ) with the composition (Q) and the profile of the section (i) along which the locomotive moves, calculate the resistance value to the movement (W) of the locomotive with the composition in accordance with the expression

,

,

where W is the resistance to movement of the locomotive with the composition;

w _o - the main specific resistance to movement;

i is the longitudinal profile of the section along which the diesel locomotive is moving, a sign (+), if it is rising, a sign (-), if it is sloping;

P is the weight of the locomotive;

Q is the weight of the composition.

For a given value of the speed of movement V _s and the calculated value of the resistance to movement W, the magnitude of the traction force F _{t of the} locomotive, which the locomotive must develop to achieve this speed, is determined, this point corresponds to point A in FIG. 2, in which the equality of traction and resistance to movement F _t = W _A is achieved.

As you know, the traction force of a locomotive F _{t is} uniquely determined by the known characteristics of the traction electric motors and the total load current of the traction motors Σ I _I or the load current of the traction generator I _g . In block 8, the calculation of the current settings of the traction generator (Fig. 1) solve the inverse problem and determine the setting of the required current value I _{g of the} traction generator from the known value of the traction force of the locomotive F _t .

In the block 10 for calculating the setpoint voltage of the traction generator (Fig. 1) according to the adjusted set point for the current of the traction generator I _gz coming from the output of block 8 for calculating the set point of current for the traction generator, a signal proportional to the magnetic flux of the traction motor is isolated by means of a functional converter 9 and fed to the first input of the multiplication unit 10, in which it is multiplied with the signal of the set value of the locomotive’s speed, V _s , received at the second input of the multiplication unit 10 from the output of the setter 5, the result This multiplication is normalized and taken as the voltage setting of the traction generator U _gz in accordance with the expression

,

,

where K is the normalizing coefficient;

SF _ted - magnetic flux of traction electric motors (determined by the well-known magnetization characteristic of the magnetic system of traction electric motors);

V _s - the set value of the speed of the locomotive.

Next, in the adder 11, the adjusted setting of the required voltage of the traction generator U _{gz1 is determined} by summing the previously obtained settings of the voltage of the traction generator U _gz and the signal from the output of the integrator 6, the voltage of the traction generator is regulated by the result.

The process of accelerating a diesel locomotive with a train to a given speed is illustrated in FIG. 2, when the operating point moves from point 0 (standing locomotive) to point A along the 0VA path, at point A, the acceleration process is completed, since all the necessary settings for the current I _gz and voltage U _{gz of the} traction generator are achieved and the equality of traction and resistance W. movement

The introduction of acceleration into the signal of the actual speed of movement allows you to indirectly take into account the effect of real resistance to movement associated with real values of the weight of the train, the current profile of the path and other factors, because acceleration is uniquely related to the mentioned factors in accordance with the equation of motion

,

,

where m is the mass of the composition;

- ускорение;

- acceleration;

F _t - locomotive traction force;

w is the specific resistance to movement;

i is the longitudinal profile of the section along which the locomotive is moving, the + sign, if it’s rising, the sign - if it’s a slope;

R _f - the real weight of the locomotive;

Q is the real weight of the composition.

Thus, the claimed invention will improve dynamic performance when controlling the speed of movement, to increase the accuracy and speed of speed control and can be used on diesel locomotives and track machines, where the nature of the activity requires increased accuracy of maintaining speed, for example, when working on shunting locomotives on the sorting slides.

The proposed method was tested on a shunting diesel locomotive TEM7A and showed good results.

Claims (1)

A method of controlling the speed of a diesel locomotive with an electric transmission, which consists in emitting a signal proportional to the actual speed of the movement, isolating a signal proportional to the magnetic flux of the traction motor, calculating the resistance to movement from the predetermined values of the weight of the diesel locomotive with the composition and profile of the movement section, from the calculated value resistance to movement and known characteristics of the traction motor determine the setpoint of the required current value of the traction generator from a natural value of the locomotive traction force, multiply the magnitude of the signal proportional to the magnetic flux of the traction motor with the value of the set value of the speed of movement, the result is taken as the set voltage of the traction generator, characterized in that the locomotive acceleration is calculated by changing the actual speed of movement in time, the calculated value is normalized and summarize with the value of the signal proportional to the actual speed of movement, compare the result with a given value, the result tat comparison integrating, by the result of the integration is corrected setpoint calculated traction generator voltage and the result obtained is adjusted traction alternator voltage.

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