EP1547956A1 - Device and method for reducing vibration in an elevator cabin - Google Patents

Abstract

The device for the reduction of oscillations of an elevator car guided on rails includes several guide elements, a sensor to record the position changes of the elevator car and/or accelerations acting upon it, an actuator between the elevator car and guide elements, and a control unit (19) with a regulator (20) which on the basis of the value transmitted from the sensor creates an output signal for the control of the actuator. A limiter unit (22) limits the output signal from the regulator to a maximum value and creates a control signal to be transmitted by the control unit.

Description

The present invention relates to a device and a method for Reduction of vibrations on a guided on rails elevator car.

While driving an elevator car in a lift shaft can different forces on the cabin body or a cabin body acting cab frame and stimulate the system to vibrate. Cause of the vibrations are in particular unevenness in the Guide rails and caused by the wind forces, which the Cabin can cause, in the horizontal direction or to one of the two Horizontal axes or to swing easily about the vertical axis. Also lateral Tensile forces transmitted by the traction cables or sudden ones Bearing changes of the load while driving can cause of Be transverse vibrations.

To the ride comfort for the elevator users and also the safety To increase the system, control systems are used, which try the to counteract forces acting on the elevator car. From the EP 0 731 051 B1 of the applicant, for example, a system is known which a plurality of movable between two end positions connected to the elevator car Having guide elements, wherein transversely to the direction of travel occurring Detects vibrations from several mounted on the cabin sensors and to Control of multiple actuators used between the cab and the Guiding elements are arranged. The actuators are thereby using a Control device controlled such that they are opposite to the occurring Working forces and thus suppress vibrations as effectively as possible.

A typical feature of these methods for active damping of vibration in elevator cabs is that the controller output or the control signal for the electric actuators must be limited, otherwise the risk of thermal overheating exists. In the publication "Thermal Protection of Electromagnetic Actuators "by E. Cortona, a method is described at the above-mentioned limitation of the control signal variable and the temperature the actuators is made dependent. This will ensure that the Actuators should not be damaged due to excessive thermal load.

Another typical property of the above-mentioned methods of active Vibration damping is further that of the position of the elevator car regulating position controller has a predominantly integrating behavior. This has to Result that with constant control deviation the output signal of the controller with the Time is getting bigger. Now the above-mentioned method of limitation used the control signal, the effect may occur that the output signal of the Position controller is getting bigger, as long as still a relatively large Control deviation exists. If the control deviation then becomes smaller again, it takes too long until the control signal has reached the desired value again.

The present invention is accordingly the object of the to avoid the disadvantages mentioned here. In particular, it should be achieved that the controller quickly after reaching the limit of the control signal again correct as soon as the position error becomes smaller again.

The object is achieved by a device for reducing vibrations of one Rail guided elevator car according to claim 1 or by a method solved according to claim 8.

The solution according to the invention is the difference between the Output signal of the controller and the limited, that is actually to the Actuators forwarded signal as an additional input to the controller attributed, wherein the controller is designed such that the recirculated Difference remains as low as possible.

The measure according to the invention, also known as anti-reset windup (ARW) is designated, it allows the not visible to the outside state variables of Regulator to change so that the difference between the actual output of the controller and the forwarded to the actuators limited output signal remains as low as possible. This ensures that the controller responds very quickly to changes in the system, especially in situations in which the position error decreases again.

According to a preferred embodiment of the present invention the return branch, via which the difference signal to the controller is returned, a time delay block, the difference signal Delayed transmitted to the controller. This ensures that in the Control system no closed algebraic loop is created. Preferably the controller operates time discretely, the time delay block the Difference signal then delayed by one sampling period back to the controller transmitted.

The maximum value to which the limiting unit outputs the value output by the controller Output signal limited, can in turn be switched dependent on temperature, the device for this purpose has a temperature sensor, the temperature the actuators captured or a mathematical model that the temperature is due the currents, the ambient temperature and the dissipation behavior of the Actuators, calculated.

The control device is preferably designed in two parts and has on the one hand a position controller, which controls the actuators such that the Guide elements against the rails occupy a predetermined position, and an acceleration controller, which controls the actuators such that on the elevator car vibrations are suppressed on. The signals of the position controller and the acceleration controller are added here and then supplied as a sum to the actuators. According to the invention in this Embodiment, the above-mentioned limiting unit with the Return branch provided only for the position controller.

By the measure according to the invention, the control behavior of the system for Vibration damping can be significantly optimized, while still ensured is that the actuators do not overheat. The reliability of the system remains therefore unchanged guaranteed.

Figur 1

eine schematische Darstellung einer an Schienen geführten Aufzugskabine, bei der das erfindungsgemäße Regelungssystem zum Einsatz kommt;

Figur 2

das Signalflussschema eines Systems zur aktiven Schwingungsdämpfung mit einem Positions- und einem Beschleunigungsregler; und

Figur 3

das Signalflussschema der erfindungsgemäß ausgestalteten Regeleinrichtung.

The invention will be explained in more detail with reference to the accompanying drawings. Show it:

FIG. 1

a schematic representation of an elevator car guided on rails, in which the control system according to the invention is used;

FIG. 2

the Signalflussschema an active vibration damping system with a position and an acceleration controller; and

FIG. 3

the signal flow diagram of the inventively designed control device.

Before the control device according to the invention with reference to Figures 2 and 3 explained will first be based on Figure 1, the realization of an overall system for active damping of vibrations of an elevator car are discussed.

The car shown in Figure 1 and generally provided with the reference numeral 1 is divided into a cabin body 2 and a car frame 3. Of the Cabin body 2 is mounted in the frame 3 by means of several rubber springs 4, which are intended for the isolation of structure-borne noise. These rubber springs 4 are relatively stiff designed to the occurrence of low-frequency vibrations to suppress.

The car 1 is by means of four roller guides 5 at the two Guide rails 15 which are in a (not shown) elevator shaft are arranged. The four roller guides 5 are usually identical constructed and mounted laterally below and above the cab frame 3. she each have a stand, mounted on the three guide rollers 6 are, two lateral and one middle role. The guide rollers 6 are each movably supported by means of a lever 7 and are on a spring 8 on the Guide rails 15 pressed. The lever 7 of the two lateral guide rollers 6 are further connected via a pull rod 9, so that they themselves move in sync with each other.

Per roller guide 5, two electric actuators 10 are provided, each exert a force on the lever 7, which acts parallel to the associated springs 8. A first actuator 10 moves the central lever 7 with the associated middle guide roller 6, whereas the second actuator 10, the two lateral lever 7 moves with the associated lateral guide rollers 6. about the actuators 10 thus the position of the lever 7 and the rollers 6 and thus the position of the elevator car 1 with respect to the guide rails 15 influenced.

• Verschiebungen in X-Richtung
• Verschiebungen in Y-Richtung
• Drehungen um die X-Achse
• Drehungen um die Y-Achse
• Drehungen um die Z-Achse

The cabin vibrations or vibrations to be damped by the device according to the present invention occur in the following five degrees of freedom:

• Shifts in the X direction
• Shifts in the Y direction
• Rotations about the X-axis
• Rotations around the Y-axis
• Rotations about the Z-axis

The various shifts or rotations in the five degrees of freedom are each on a different storage of the elevator car 1 to the four roller guides 5 due in the X and / or Y direction.

To vibrations of the cabin 1 in all five above degrees of freedom To be able to grasp, two position sensors 11 are initially per roller guide 5 provided, a first sensor for detecting the position of the central lever 7 with the associated guide roller 6 and a second sensor for detecting the position of two lateral lever 7 with the associated lateral guide rollers. 6 In addition, each roller guide 5 with two horizontally aligned Acceleration sensors 12 equipped, one of which accelerations in Displacement direction of the middle guide roller 6 and the second Accelerations perpendicular to it in the direction of displacement of the two lateral Guide rollers 6 detected. The measuring signals of the sensors 11 and 12 provide information about the current position of the elevator car 1 with respect to the two Guide rails 15 and also inform about whether the cabin body 1 current accelerations, which can lead to vibrations.

On one of the roller guides 5 (here on the right upper roller guide) is Further, a rotational movement sensor 13 is provided, the rotation angle of a him associated guide roller 6 measures. The about this rotary motion sensor 13th The measured values obtained provide information about the travel path of the car as well as about their current driving speed in vertical, ie in the Z direction. One on the Ceiling of the cab body 2 attached controller 14 finally processes the from the sensors 11 and 12 transmitted signals and controls the evaluation of the Sensor signals by means of a power section, the electric actuators 10 of the four Roller guides 5 to the accelerations and vibrations in a suitable Counteract way.

FIGS. 2 and 3 show the signal flow diagram of the system according to the invention for active vibration damping. The basic structure according to FIG. 2 corresponds essentially to the method, as it also in the EP 0 731 051 B1 is used. The signals shown are as To understand vector signals which comprise a plurality of signals of the same kind. The Control device is a so-called MIMO (multi-input multi-output) controller configured, based on several input signals, several control signals for determines the located on the roller guides actuators.

In the system shown in Figure 1 act on the cabin 1 external disturbances, which are composed of indirect disturbing forces from the rails 15 and from directly acting on the cabin 1 disturbing forces 16 in the form of cabin load, rope and wind forces. With the aid of the position sensors 11 and the acceleration sensors 12, the current state of the car is determined, wherein first the positions measured by the position sensors 11 are compared in a summation block 17 with reference values which represent a reference position of the car 1 with respect to the rails 15. The result of the summation is the error signal or the control deviation ep, which describes the deviations of the positions of the roller guides with respect to the reference position. In contrast, in the summation block 18, the acceleration values of the acceleration sensors 12 are negated, ie subtracted from the ideal or reference value 0 (no accelerations), whereby the second error signal e _{a is} generated.

The controller 19 is composed, as already mentioned, of two controllers, a position controller (K _p ) 20 and an acceleration controller (K _a ) 21. The reason for using two separate controllers is that a target of the controller 19 is cabin vibrations in the high frequency range (between 0.9 and 15 Hz, and preferably between 0.9 and 5 Hz) without the controlled elevator outside this frequency range behaving worse than the unregulated. On the other hand, the control device 19 must ensure that the setting of the cabin frame 3 with respect to the guide rails 15 is controlled so that at any time a sufficient Dämpfungsweg is available to the rollers. This is particularly important when the car 1 is loaded asymmetrically.

For the first control purpose is an acceleration or Velocity feedback with inertial sensors sufficient, while however, a position feedback is required for the second control target. Both returns have two contradictory goals, which are determined by the Using the two separate controllers 20 and 21 are tracked. As in figure 2, the position controller 20 takes into account only the measured values the position sensors 11 and is accordingly for the maintenance of the Leading games of the cabin 1 responsible. The acceleration controller 21 on the other hand, it processes the measured values of the acceleration sensors 12 and is responsible for the Suppression of vibrations required. The setpoints or set values of both Regulator 20 and 21 are added in the summation block 23 and as a common actuating signal supplied to the actuators 10.

The solution to avoiding the above-mentioned conflict between the two Regulators 20 and 21 is based on the circumstance that for an imbalance of Cabin 1 responsible forces (a non-symmetrical loading of the cabin, a large lateral cable force and the like) change much more slowly than the other sources of interference that cause the cabin vibrations. in this connection These are mainly rail unevenness or air disturbances. The Amplification changes in the frequency domain are always continuous, that is: there are no fixed limits. At a certain frequency both controllers have 20 and 21 the same amount of influence. In addition, the acceleration controller 21 acts stronger, underneath, the position regulator 20 acts more strongly.

By the subdivision of the control device 19 in a position control loop as well An acceleration control loop can thus both be mentioned above To be tracked. Another advantage of the subdivision is further in that the controllers 20 and 21 contain no non-linearities. Otherwise, would be a stability analysis and thus a corresponding configuration of the two Controller difficult.

However, in the present case, the output signal F _{P of} the position controller 20 is initially supplied to a limiting unit 22, which limits the signal to a maximum amount F _max . The thus generated limited output signal F _Pl , for the F pl = max [min (F P , F Max ), -F Max ] applies, is finally added in the block 23 with the control signal F _{a of} the acceleration controller 21 and the actuator or 10 supplied.

The maximum size F _{max of} the limiting unit 22 is dependent on the thermal load capacity of the electric actuators 10 and thus on their current temperature T _act . For this purpose, temperature sensors are attached to the actuators (not shown in FIG. 1), which transmit a corresponding signal to the control unit 19, which then supplies the limiting unit 22 with the corresponding maximum value F _max (T _act ). Instead of measurement, the temperature T _act can be determined by a mathematical model. This takes into account the currents at the actuators 10, the ambient temperature and the dissipation behavior of the actuators 10.

The limitation on the output signal of the position controller 20 carried out in the previous manner has the consequence that the "theoretically optimal" actuating signal F _P ascertained by the controller 20 continues to increase, provided that deviations from the optimum position are present over a relatively long period of time. The reason for this is that the position controller 20 has a predominantly integrating behavior. The consequence of this would be that if the control deviation drops again, it takes too long until the output signal F _{P of} the controller 20 has again reached the desired value, so that the controller can respond to the new situation. In order to circumvent this problem, an expansion of the control loop is provided according to the invention, which will now be discussed with reference to FIG. In this case, only the control device 19 is shown in Figure 3, since the other components of the signal flow diagram shown in Figure 2 remain unchanged.

The extension according to the invention consists in the fact that now a return path is provided, via which the position controller 20, a further input signal is supplied. This further input signal is the difference between the output signal F _{P of} the controller 20 and the limited output signal F _Pl output by the limiting unit 22. Both values are fed to a summation block 24, which forms the difference e ^F _k . The error signal determined in this way is then fed to a time delay block (z ^-1 ) 25, which returns the signal as an input signal e ^K _k-1 to the position controller 20 with a time delay, preferably by one sampling period of the time-discretely operating regulating device 19. The time delay of this error signal is required so that no closed algebraic loop is formed in the control system.

The position controller 20 thus receives now in addition to the error signal e _p with respect to the position of the car 1 also another input signal e ^F _k-1 in the form of the difference signal between the output signal F _P and the limited output signal F _Pl . The controller 20 is designed in such a way that the difference signal e ^F k remains as small as possible. The output signal F _{P of} the position controller 20 should thus be limited only slightly by the limiting unit 22. This ensures that in the event that the position error signal e _p again assumes a smaller value after a temporary period with higher deviations, the controller can react as promptly as possible to the new situation. This is now possible since the effect can no longer occur that the output signal of the controller 20 drifts significantly above the maximum value F _{max of} the limiting unit 22.

The implementation of the feedback branch into the controller is achieved by extending the position controller 20 by a so-called Anti-Reset Windup (ARW) algorithm. This algorithm alters the internal state variables x of the position controller 20 such that the difference signal e ^F _k remains as small as possible in the desired manner. The equations describing the linear behavior of the position controller x k + 1 = A P x k + B P e P F P, k = C P x k + D P e P For this purpose, a so-called ARW matrix B ^{ARW is} extended, resulting in the following system of equations describing the behavior of the system to be controlled:

The calculation of the ARW matrix then takes place in the design of the controller with the so-called H∞ method. This is a - for example from the publication "Robust Control" by Hans P. Geering, IMRT-Press, Institute for Measurement and Control Control technology of the Swiss Federal Institute of Technology Zurich - known Method by which a controller with knowledge of the behavior of the system to be controlled can be designed, the main advantage of this method being that it can be automated as far as possible. In the present case with the Extended loop then additional information is used otherwise remain unused. The application of the H∞ method and the For example, calculation of the ARW matrix is also from U. Christen: Engineering Aspects of H∞ Control, Diss. ETH No. 11433 (1996).

It should be noted that in the illustrated subdivision of the control device in the Both control circuits, the limitation and inventive feedback only for the output signal of the position controller is performed, which in turn with related to the integrating behavior of the position controller. Of the Acceleration controller, however, has - as mentioned - rather the behavior of a Bandpass filter. Because of him to the dominant processes much faster are the position changes to be compensated by the position controller Cabin, there is no danger that the actuators by the control signals of the Acceleration controller permanently loaded on one side and thus the risk overheating.

By the solution according to the invention is thus ensured that the Position controller in the desired manner quickly changing conditions can react. In particular, the controller achieved by means of the invention Extension even in the event that the position error signal for a longer Period assumes a higher value, quickly the desired new control value, as soon as the position error signal falls back to a lower value. simultaneously However, it is ensured that the control signal of the controller, the predetermined Does not exceed maximum values and thus the actuators do not run the risk of to be damaged due to excessive thermal stress.

Claims (14)

Device for reducing vibrations of an elevator car (1) guided on rails (15), comprising: a plurality of guide elements (5, 6, 7) for guiding the elevator car (1) along the rails (15), a sensor (11, 12) for detecting changes in position of the elevator car (1) and / or accelerations occurring at the elevator car (1), a between the elevator car (1) and the guide elements (5, 6, 7) arranged actuator (1) and a control device (19) which, on the basis of the values transmitted by the sensor (11, 12), actuates the actuator (10) for changing the position of the car (1) relative to the rails (15), the control device (19) points a) a controller (20) which generates an output signal for driving the actuator (10) on the basis of the values transmitted by the sensor (11, 12), as well as b) a limiting unit (22) which limits the output signal output by the controller (20) to a maximum value and in this way generates the actuating signal to be output by the control device (19), on,
the control device (19) further has a feedback path (24, 25) via which the regulator (20) is supplied with the difference between the output signal of the regulator (20) and the limited output signal generated by the limiting unit (22) as a further input signal,
the controller (20) is designed such that the returned difference remains as low as possible. Device according to claim 1,
characterized in that the feedback branch comprises a time delay block (25) which retransmitted the difference between the output signal of the regulator (20) and the limited output signal generated by the limiting unit (22) to the regulator (20) in a time-delayed manner. Device according to claim 2,
characterized in that the control device (19) operates time discretely, wherein the time delay block (25) the differential signal by a sampling period with a time delay transmitted to the controller (20). Device according to one of claims 1 to 3,
characterized in that the maximum value to which the limiting unit limits the output signal output by the controller (20) is temperature-dependent. Device according to claim 4,
characterized in that the maximum value depends on the temperature of the actuator (10), wherein the device further comprises at least one temperature sensor of the actuator (10) detecting temperature sensor, the measurement signals of the limiting unit (22) are supplied or instead of a measurement, the temperature of Actuator (10) can be determined by a mathematical, thermal model. Device according to one of the preceding claims,
characterized in that the control device (19) comprises: a position controller (20) which controls the actuator (10) in response to signals from position sensors (11) arranged on the elevator car (1) in such a way that the guide elements (5, 6, 7) assume a predetermined position and an acceleration controller (21) which controls the actuator (10) in response to signals from acceleration sensors (12) arranged on the elevator car (1) in such a way that vibrations occurring at the elevator car (1) are suppressed, wherein the control signals of the position controller (20) and the acceleration regulator (21) are added and supplied to the actuator (10) as a sum signal. Device according to claim 6,
characterized in that the limiting unit (22) and the return branch (24, 25) are provided only for limiting and returning the output signal output by the position controller (20). Method for reducing vibrations of an elevator car (1) guided on rails (15), the cabin comprising: a plurality of guide elements (5, 6, 7) for guiding the elevator car (1) along the rails (15), a sensor (11, 12) for detecting changes in position of the elevator car (1) and / or accelerations occurring at the elevator car (1), a between the elevator car (1) and the guide elements (5, 6, 7) arranged actuator (1), and a control device (19) which, on the basis of the values transmitted by the sensor (11, 12), actuates the actuator (10) for changing the position of the car (1) relative to the rails (15), wherein the output signal generated by a controller (20) provided in the control device (19) for driving the actuator (10) is limited to a maximum value and in this way an actuating signal to be output by the control device (19) is generated,
wherein the difference between the output signal of the regulator (20) and the limited output signal is supplied to the regulator (20) as an additional input signal, and
wherein the controller (20) is designed such that the returned difference remains as low as possible. Method according to claim 8,
characterized in that the feedback of the difference between the output signal of the controller (20) and the limited output signal is delayed. Method according to claim 9,
characterized in that the control device (19) operates time-discretely, the feedback being delayed by one sampling period. Method according to one of claims 8 to 10,
characterized in that the maximum value to which the output signal output by the controller (20) is limited, is temperature-dependent. Method according to claim 11,
characterized in that the maximum value depends on the temperature of the actuator (10). Method according to one of claims 8 to 12,
characterized in that the control device (19) a position controller (20) which controls the actuator (10) in response to signals from position sensors (11) arranged on the elevator car (1) in such a way that the guide elements (5, 6, 7) assume a predetermined position and an acceleration controller (21) which controls the actuator (10) in response to signals from acceleration sensors (12) arranged on the elevator car (1) in such a way that vibrations occurring at the elevator car (1) are suppressed, wherein the control signals of the position controller (20) and the acceleration regulator (21) are added and supplied to the actuator (10) as a sum signal. Method according to claim 13,
characterized in that only the output signal of the position controller (20) is limited and returned.

Images