DE19629739C1 - Drive control mechanism, with measurement system, for load movable in several spatial dimensions e.g. for vehicles, air- and space-craft, and buildings vibration test stand - Google Patents

Abstract

The control mechanism includes several actuators operating respectively in a single dimension, which are coupled to the load and are controlled through respectively one electronic drive control mechanism. The electronic drive control mechanism receives nominal kinetic values as well as nominal force- or torque values for its actuator. The drive control mechanisms (4) are connected to a nominal value converter (5), which receives nominal kinetic values for the load (1) in a coordinate system, and transforms them on the basis of the geometric arrangement of the connected actuators, into the corresponding nominal kinetic values for the individual actuators. The nominal value converter determines nominal force- or torque values for the load under application of predetermined characteristics of the load, which describe the dynamic behaviour of the load as a rigid body, and transforms them into the corresponding nominal force- or torque values for the connected actuators.

Description

The invention relates to a controller for driving one in several rooms dimensions moving load and systems for measuring movement states or dynamic parameters of such a load, the Measuring systems in particular for regulating and monitoring the Movement states of the load are suitable.

Areas of application of the invention are firstly vibration test benches, including shakers in which the vibration behavior of vehicles, aircraft, Spacecraft, buildings, their components and many others technical facilities in response to vibrations or shocks in all three Room dimensions can be checked. These include, for example, earth beben test benches, test benches for power plant components, in particular from Nuclear power plants, test benches for railways or bicycles and satellites test benches.

Second, the invention is suitable for use on test benches for investigation reaction behavior or durability of vehicle components  with arousal in very specific places. These include in particular Axle test benches in the automotive industry that simulate driving can be by clicking on the wheels or their attachment points on the axle time-varying forces are exerted, as in real situations occur.

A third important field of application of the invention is flight and driving simulators in which a cabin is to be moved so that the occupants in Connection with appropriate visual and / or acoustic indicators Get flight and driving impressions as realistic as possible.

Such devices are moved by a number of actuators transferred. Actuators for vibration frequencies up to about 100 Hz valve-controlled hydraulic cylinders have been proven to provide the required travel ranges produce. Electromechanical actuators come in for higher frequencies Consider, for example, electromagnetic, piezoelectric or magnetostrictive working actuators.

The actuators in question each have a one-dimensional effect. Hydrau lische and many electromechanical actuators are linear actuators, their Effect z. B. consists in a change in length or speed. The However, the invention is also applicable in cases where the load is partial or is driven exclusively by rotary actuators, for example by Servomotors is rotated.

The number of actuators required and their points of attack on the load are usually due to design requirements or requirements gene conditional. Therefore, the actuators are not controlled independently of one another bar if you want to achieve a certain movement of the load. In case of several hydraulic cylinders that move in different directions which points are coupled to the load has, for example, a path adjustment one of the hydraulic cylinders results in a curvilinear movement of the load.  

In addition, the positions of the cylinder axes change in space.

On the other hand, they lie either through measurements in reality or through suitable models received movements or forces that make up the load should be set in a fixed coordinate system that has a number of coordinates that represent the movements or forces are necessary and sufficient, for example the Cartesian Coordinate system.

In DE 43 15 626 C1, which is an electronic drive control for a hydraulic actuator relates to a predetermined setpoint curve for the Acceleration of the hydraulic cylinder and setpoints calculated from it the speed and the path of the hydraulic cylinder and for those on it receives acting force and controls the actuator on the basis of these signals, it is proposed, in the case of multi-axis systems, the force coupling to determine the axes among themselves using a geometry calculator.

In the publication ESA SP-197 "Space Force Vibration Testing using Multi-Axis Hydraulic Vibration Systems "by the European Space Agency, July 1983, is published in the contribution "Control of Multi-Axis Vibration Systems" by A. Schmidt, Pages 75-89, proposed to linearize the behavior of the test facility and described by linear equations.

Such an approach is generally considered the only way predetermined setpoints for the movement of the load in control signals for the Convert actuators. The shortcomings due to linearization one tries to counter with standard control techniques.

A similar problem exists in the event that the movements of the load and the forces acting on it are sensed by sensors, either for Monitoring or to receive signals to be returned to the Control can be used for regulation. In this case, too  are technical design factors responsible for ensuring that the Sensor signals generally do not directly deal with the real movements or forces can specify. For forming these sizes into sizes that match the So far, input variables of the system are comparable only linearized models considered.

The invention has for its object a very precise control Drive of a load moving in several room dimensions as well as systems for the very precise measurement of their movement states or dynamic To create parameters.

This task becomes one with a control for drives in several rooms dimensions movable load, with several acting one-dimensional Actuators in different directions and / or in different places the load are coupled and each with an electronic drive control can be controlled, the kinematic setpoints and force or torque receives setpoints for the actuator, solved according to the invention in that the Drive controls or at least two of the drive controls are connected together to a setpoint converter, the kinematic Receives setpoints for the load in a coordinate system and the

• a) the kinematic setpoints for the load based on the geometric Arrangement of the actuators in the corresponding kinematic setpoints for converts the connected actuators and
• b) using predetermined parameters of the load, which the dynamic properties of the load as a rigid body essentially fully describe force and / or torque setpoints for the load determined and in the corresponding force or torque setpoints for the connected actuators.

In the majority of the applications described above, the kinemati setpoints for the load paths, speeds and accelerations, each in Cartesian coordinates as a function of time, and are the actuators Ren linear actuators, such as valve-controlled hydraulic cylinders, so that the kinematic setpoints for these actuators also travel, speed speeds and accelerations. If in relation to one or more rooms Dimensions are essentially to produce rotary movements, for example for torsional vibration tests, but it can also be useful, the target values with respect to these spatial dimensions as angles, angular velocities and angular accelerations and in corresponding setpoints for Convert rotary actuators to the load.

In cases where the load to be moved is not just the under load Searching or moving object, but for example as with most Test benches a movable table, the test object and fasteners to attach the test object to the table, the entire movable arrangement treated as a rigid body, its dynamic Properties for forming the force or torque setpoints for the Actuators are used.

The dynamic properties of such rigid bodies can be very precisely describe and record with the model of an ellipsoid of inertia, d. H. under assuming an ellipsoidal model body with uniform masses distribution that has the same moments of inertia and the same mass as that has real object. If you look at the entire moving object as such If the ellipsoid of inertia is taken into account, the forces acting on the individual actua gates to generate the desired movement of the load (in the case of rotary actuators, torques), based on the kinematic target calculate the values of the load very precisely. This calculation is preferred carried out on the condition that the sum of the squares of all Forces or torques of the actuators is minimal, so that the total required effort is minimized.  

In many applications there are certain symmetries in the arrangement of the Actuators so that they form essentially identical groups. It it is then advantageous to provide several essentially identical setpoint converters watch that each control the drive controls of one of the actuator groups. Each of the setpoint converters can be of simpler construction than if they were all Actuators would have to be controlled together, and the required number of target value converters can be made by duplication, which is particularly true in the Case where the setpoint conversion is not in a hard-wired circuit, but is done programmatically on a universal computer, very expensive is cheap to carry out. Incidentally, both are those described above Control as well as the measuring, regulating and Monitoring systems can be implemented in software as well as in hardware, preferably with digital signal processing.

The kinematic setpoints for the load are distances, speeds and Accelerations as a function of time in advance by measurements in the Reality or be gained through models. The parameters of the load, which the dynamic properties of the load are essentially complete can also describe by separate measurement or by model bills are won. However, the latter is often only significant Effort or not possible with the desired accuracy.

The invention now also provides a measuring system for one in several Raumdi dimensions movable load, the control described above is excellent added as it provides accurate measurements of the actual movement of the load, which are used advantageously in connection with the control for regulation can. These measurements of the actual movement of the load can be in a Further development of the measuring system according to the invention can be used to measure the dynamic parameters of the load to determine the control. As a result, no separate measurements or Model calculations required, and the dynamic parameters of the load can be determined directly on the test bench or the like. With Values obtained with the help of this measuring system are much more precise and deliver  more information than conventional, linearized measurement methods, making it also advantageous regardless of the control described above can be used.

The measuring system according to the invention for one in several spatial dimensions moving load, in different directions and / or in different If several actuators that act one-dimensionally are coupled, which are provided with travel sensors, as described in the above DE 43 15 626 C1 used for valve control comprises several Speed sensors and several acceleration sensors, which Load speeds or accelerations at various points sense and their number at least equal to the number of degrees of freedom the load, and a transducer that receives the signals from the travel sensors, receives the speed sensors and the acceleration sensors and without linearization in kinematic actual values for the load in one coordinate system converts.

The coordinate system for the kinematic actual values of the load, which in many Cases are actual routes, actual speeds and actual accelerations is more normal have the same coordinate system as that for the kinematic setpoints with the control described above. Therefore, the kinematic actual values and setpoints can be compared directly, and there can be a control loop are formed, the control according to the invention and the fiction appropriate measuring system includes.

In a development of the measuring system according to the invention is also on a force sensor is provided for each actuator, the transducer using the obtained kinematic actual values of the load and the Signals generated by the force sensors signals the dynamic properties of the Load as a rigid body essentially entirely in the coordinate system describe.  

The dynamic properties of the load as a rigid body are preferred by their mass, their center of gravity and their main axes of inertia with the associated moments of inertia.

If this measuring system in connection with the described control ver is applied, the dynamic properties of the load need not be in advance can be determined and entered, but can be determined automatically in an identification run.

Another measuring system according to the invention for one in several rooms dimensions moving load to which in different directions and / or various actuators each acting one-dimensionally are coupled, which are provided with force sensors, comprises a measured value transducer that receives the signals from the force sensors and without linearization in converts actual kinematic values for the load in a coordinate system.

This measuring system is ideally suited for monitoring a multiple axis system on critical movement states of the load, since the movements, Load speeds and accelerations ultimately all depend on the forces decrease that are exerted by the individual actuators. Because besides the force sensors require no further sensors, the transfer takes place watch very reliable. In addition, force sensors are often very anyway reliable sensors, for example in the case of pressure sensors such as these be used with hydraulic actuators.

This measuring system, which only dynamic actual values such as forces or Processed pressures, is also ideal for simulations, in for whom the system has not yet been fully set up. To generate the Kinematic actual values, which may also be used to control the above described control can be used, actual force values are sufficient, which are either actually measured or generated by actuator simulators can be connected to the controller. For this measuring system  Using simulated actuators can even with a complete system gene configuration with real actuators working in parallel can be useful because due to integration with time results in an error that occurs during the simulation can be narrowed down.

The systems described are based on the common idea, contrary to Previously applied practice to linearize the respective Dispense with input variables and put them as precisely as possible into the respective To transform output variables. It has been shown that such a transformation is not only feasible in principle, but can also be carried out in real time, d. H. at a time that is significantly shorter than the time constant or the inverse Maximum frequency of the load movements is.

The systems described can therefore have any control or measurement signals not only very precisely, but also very quickly and are suitable thus not only slow to process, but also quickly changeable or high-frequency signals, as well as for a variety of types of such signals, such as sinusoidal signals, broadband noise or transients, d. H. a narrowband noise (impulse response). Play transient accelerations e.g. B. with satellites in the starting phase an important role.

Due to the exact forming, there are any test specimens and any frequency converging solutions, unlike conventional ones Systems that are only suitable for some excitation signal forms or for some test objects or frequencies to non-converging solutions to lead.

As mentioned, the control and measuring systems according to the invention are closed can be combined in an advantageous overall system, namely a control and / or Control of a multi-axis system with measurement data analysis and / or automatic determination of the dynamic parameters of the load and / or Monitoring of the kinematic actual values of the load. The occurring  Nonlinearities can be completely controlled.

Further features and advantages of the invention result from the Unteran say and from the following description of several embodiments based on the drawing. In it show:

Fig. 1 is a block diagram of the electronic and mechanical control, measurement, control and monitoring equipment of a satellite test bed, with a schematically depicted in perspective view of the movable inspection table;

Figure 2 is a schematic flow diagram of the operation of the setpoint converter.

Fig. 3 is a schematic flow diagram of the operation of the transducer for kinematic and dynamic actual values of the load; and

Fig. 4 is a schematic flow diagram of the operation of the transducer for dynamic actual values of the load.

A table 1 shown octagonally in FIG. 1 is mounted on eight actuators in the form of valve-controlled hydraulic cylinders. Four actuators are arranged in the table plane symmetrically around table 1 , and four actuators are in a square perpendicularly below table 1 . The eight actuators, of which only one horizontal actuator 2 and one vertical actuator 3 are shown in the figure, are supported on their sides facing away from the table 1 on a foundation (not shown). The table 1 can be moved with the help of the actuators in all six spatial degrees of freedom (translations and rotations with respect to the Cartesian coordinate system shown with the center of the table as the origin).

On the table 1 , a test load, not shown, can be attached, e.g. B. a satellite. In order to be able to realistically simulate not only the forces and accelerations acting in the longitudinal direction of the rocket, but also transverse accelerations and forces, the satellite can be placed at a height above table 1 which corresponds to the height of the rocket or the uppermost rocket component. The load to be moved consists of the test table, the satellite and the necessary fasteners. In addition, the moving part of the actuators is included in the total load.

Each actuator 2 , 3 is connected to an electric drive control 4 . Each drive controller 4 , which can be designed in detail, for example, as described in DE 43 15 626 C1, controls the associated actuator 2 , 3 in accordance with continuously received input variables for the path, the speed and the acceleration along the axis of this actuator as well as for the force that this actuator should exert on the table 1 at all times. Each drive control 4 can contain internal control loops.

The drive controls 4 are connected to a setpoint converter 5 , from which they receive the - time-dependent - setpoints for the path, the speed, the acceleration and the force. In this example, these setpoints or manipulated variables are the travel path, the travel speed and the travel acceleration, but they can also include the "travel jerk" and other derivatives, as well as the actuator force of the actuators 2 , which in this case operate linearly, with torques in the case of rotary actuators would be used.

The setpoint converter 5 receives as input variables E time-dependent setpoints for the path, the speed and the acceleration which the load is to experience. These setpoints derived from measurements during rocket launches or, for example, from engine tests each have six degrees of freedom, namely three degrees of freedom of translation and three degrees of freedom of rotation, and are each specified in a suitable coordinate system, e.g. B. in Cartesian coordinates.

These target values for the path, the speed and the acceleration in six degrees of freedom are converted by the target value converter 5 into the individual target paths, target speeds and target accelerations for the connected actuators 2 , 3 on the basis of the known geometric arrangement of the actuators.

Furthermore, the characteristics of the load are entered into the setpoint converter 5 , which describe the dynamic properties of the load as a rigid body in essence completely. In the example described, these parameters are the mass M of the load, the location S of its center of gravity and the mutually perpendicular main axes of inertia or main axes of the load with the associated moments of inertia. These parameters have ten degrees of freedom: one for the mass, three for the location of the center of gravity, three for the orientation of the main axes of inertia in space and three for the amounts of the moments of inertia.

With the aid of these parameters, the setpoint converter 5 determines the force and torque setpoints F , M for the load from the acceleration setpoints and transforms them into force setpoints F₁, F₂ for the connected actuators 2 , 3 .

The mode of operation of the setpoint converter 5 , which is shown in simplified form in the flowchart in FIG. 2, is explained in more detail below. The mathematical methods specified in this and the exemplary embodiments explained later in connection with FIGS. 3 and 4 have proven to be suitable for carrying out the calculation in real time. In addition to these methods, there may be other methods that allow real-time calculation.

First, some definitions are made.

A solid body in space describes six-dimensional movements (three of translation and three of rotation). Without restricting generality, the movement can be described with (3,2,1) Euler angles, ie the movement is made up of images
Rotation X: P → P₁
Rotation Y: P₁ → P₂
Rotation Z: P₂ → P₃
Translation T: P₃ → Q
together with an arbitrary body point P, which is transferred to a point Q. The rotations rotation X, rotation Y and rotation Z are those about the axes X, Y and Z of a fixed spatial coordinate system and the translation T is a three-dimensional shift of the already "rotated" point vector P₃ into the output vector Q.

The entire movement is therefore determined by the sizes

Angle of rotation α _x , α _y , α _z
and translation vector with the components T _x , T _y , T _z

described. These movements are common - as in the following - Functions of time.

In addition to the movement variables, which depend on the location of the body Describing time, speeds, accelerations, forces often occur etc. as variables to be controlled. Will the movement sizes once again differentiated in time, one speaks of rotational or translational speed efficiency. If the movement quantities are differentiated twice according to time, then one speaks of rotational or translational acceleration.

The variables listed above are referred to below as the kinematic target sizes or setpoints. If appropriate sizes on actual Movements of a body are based, they are called actual kinematic quantities or Actual values.  

As dynamic, in the one-dimensional case of the force corresponding quantities become those acting on the body

Moments about the axes X, Y or ZM _x , M _y , M _z
and forces in the direction of the axes X, Y and ZF _x , F _y , F _z

referred to, whereby a distinction is also made between target and actual values.

The following calculations relate to the case that the axes X, Y and Z are the unit axes of a coordinate system which is related to the Fastening points of the actuators on a foundation is fixed. A Verall Allocation to any coordinate system is easy to do.

The system also has the following parameters:
P₁, P₂,. . ., P _m are the fastenings of actuators on the moving body in the case of α _x = α _y = α _z = 0 and T _x = T _y = T _z (zero point position of the system);
Q₁, Q₂,. . ., Q _m are the attachments of the actuators to the foundation;
M is the moving mass of the body;
S is the location of the center of gravity;
A, B, C are the main axes of the ellipsoid of inertia.

With the exception of the mass, these parameters are of course vectors, to the association fold the representation, they are not particularly marked as such.

The geometric implementation of the setpoints α _x , α _y , α _z and T _x , T _y , T _z in actuator coordinates can then be described by

with unchanged foundation coordinates in the case under consideration and modified points of attack on the moving mass. Γ is the so-called Rotation matrix that contains the trigonometric relationships with which the Rotation angle can be transformed into Cartesian coordinates.

The forces and torques that are at zero in the rest position Attacking the "center point" of the moving body can be done vectorially describe as

and torques

Since the forces F _x , F _y , F _z and torques M _x , M _y , M _z with the actuator forces F 1, F 2,. . ., F _m in a linear relationship of the shape that can be calculated from the geometric relationships

where X ∈ R ^{6xm contains} the calculable matrix, the actuator ^forces can now be determined according to their direction of action:

wherein the pseudo-inverse of X may be taken for Y = (X · X ^{T) -1} · X ^T. This corresponds to an equal distribution (in the sense of the smallest squares) of the forces on all actuators. In cases where this is not desired, the method can easily be extended to unequal distributions.

This ends the calculation of the kinematic setpoints and the force setpoints or dynamic setpoints for the individual actuators. As summarized in Fig. 2, the setpoint converter 5 thus calculates in a first step S21 the target paths, target speeds and target accelerations for the individual actuators and leads them to the drive controls. In a second method step S22, the setpoint converter 5 calculates the force setpoints for the actuators from the setpoints, setpoints and setpoint accelerations using predetermined dynamic parameters and also feeds them to the drive controls. The process steps S21 and S22 are carried out continuously and in real time.

In the construction of the control system shown in FIG. 1, the setpoint converter 5 is only connected to two drive control systems 4 which control the actuators 2 , 3 . In this case it is therefore sufficient if the setpoint converter generates the setpoints for these two actuators, which simplifies and accelerates the calculation. In addition to the setpoint converter 5 , three further, similar setpoint converters are provided, which also receive the input variables E, each of the four setpoint converters controlling two drive controls for a pair of horizontal and one vertical actuators (one of these setpoint converters 5 working in parallel is together with the two connected drive controls 4 shown in dashed lines). Such a division of the setpoint conversion into parallel processes is particularly advantageous in cases in which symmetry relationships exist between different groups of actuators, in the case of the octagonal table 1 by the regular arrangement of two actuators 2 , 3 at four corners. However, the setpoints for all actuators can also be generated and output by a single setpoint converter 5 .

Each actuator 2 , 3 contains a travel sensor 6 for the direct measurement of the actuator stroke s and a speed sensor 7 for the direct measurement of the actuator speed v, ie the change over time of the actuator stroke s.

In addition, 1 acceleration sensors 8 are attached to certain locations on the table that are as far apart as possible. The acceleration sensors 8 are preferably constructed and attached to the table 1 in such a way that they measure the acceleration a of the table 1 perpendicular to the table surface at its attachment point. The number of acceleration sensors 8 is typically eight or twelve in the geometry of table 1 shown in FIG. 1. With other table geometries, a different number of acceleration sensors can be useful; however, at least as many acceleration sensors are required as the table has 1 degree of freedom.

Also connected to the actuators 2 , 3 are pressure sensors 9 , which measure the respective cylinder pressure differences Δp, which represent a measure of the forces which the individual actuators 2 , 3 exert on the table 1 . In the case of electromechanical actuators, it may also be expedient to sense these forces directly.

The signals from the travel sensors 6 , the speed sensors 7 , the acceleration sensors 8 and the pressure sensors 9 , which are continuously measured, are fed to a transducer 10 which operates as follows.

The position of the table 1 in the coordinate system used is calculated from the actuator travel paths s, which are obtained from the travel path sensors 6 , more precisely the translation and the rotation of the table 1 with respect to the coordinate origin, that is to say a variable with six degrees of freedom (method step S31 , Fig. 3).

From the thus calculated position of the table 1 and the actuator speeds v, which are obtained from the speed sensors 6 , the speed of the table center is calculated, which is also a variable with six degrees of freedom (method step S32, Fig. 3).

The acceleration of the center of the table 1 , which is also a variable with six degrees of freedom, is calculated from the results for the position and the speed of the table 1 and the acceleration values a obtained from the acceleration sensors 8, which are obtained in the previous calculations. Method step S33, Fig. 3).

Method step S31 requires a relatively complex, non-linear calculation nung. The six-dimensional movement of the body can still be in real time are determined, iteratively in one or more iteration steps per measuring loop, e.g. B. by the multi-dimensional Newton-Raphson method or comparable methods for inversion.

For example (in the case of linear actuators) is the travel path of the actuators through

given as a function of the rotation angle α _x , α _y , α _z and the translation vector with the components T _x , T _y , T _z , and actuator travel paths I 1, I 2,. . ., I _{m have been} determined, the rotation angle and translation vector are to be determined such that for k = 1, 2,. . ., m the equations

are fulfilled. According to a mathematical method, α _x , α _y , α _z and T _x , T _y , T _z are now determined so that the sum of the squares

becomes minimal. This method ("least squares method") can also by other, possibly more appropriate in the respective application Methods to be replaced. The mathematical method mentioned is in highly non-linear. In practical applications, it is often only iterative solvable. However, it can be used in real time if the measuring loops are one have a sufficiently high frequency compared to the useful signal frequency, in very few or even only one iteration step can be resolved if as Starting value of the iteration, the previous result is selected.

Following the determination of the travel paths are in the procedure S32 and S33 the speeds and accelerations of the Body determined by the least squares method. after the Travels are determined, this mathematical method is only linear, d. H. can be resolved in one step. The only requirement is that the measured Speeds or accelerations on the moving body itself or along the actuators are detected.

Since the above calculations of the kinematic actual values of the table 1 can be carried out online in one or more data processing systems, that is to say at a speed which allows a comparison with the target values on the basis of which the table 1 is moved by means of the actuators 2 , 3 , they can be operated with Kinematic actual values obtained with the aid of the transducer 10 can be used for regulating the table drive. For this purpose, they are output at A in FIG. 1 to a control device, not shown, which can suitably react to the input signal of the setpoint converter 5 at E.

In the measured value converter 10 , the forces and torques which act on the fixed coordinate origin at the table 1 are also determined in a simple manner (method step S34, FIG. 3). For this purpose, only the forces which the individual actuators exert and which are implicitly given by the cylinder pressure differences Δp are required.

From these forces and torques, the mass M of the total load is also determined, which is formed by the table 1 , the actuators 2 , 3 , the payload, for example the satellite to be tested, and fastening elements etc. (method step S35). This can be carried out in a static calibration phase without excitation, the mass simply resulting from the sum of the force vectors obtained during this phase in the normal case of a vertically acting gravitational force.

In an excitation phase, the continuously determined forces and torques that act on table 1 are used to fully calculate the location S of the center of gravity of the total load (method step S36).

The mass, the location of the center of gravity in relation to the coordinate origin and the online measurements of the forces and torques acting on table 1 , and the position of table 1 are then used to determine the main axes of inertia and associated moments of inertia of the total load, if one considers them as an ellipsoid of inertia (method step S37).

The calculations in the context of method steps S34 to S37 can be based on the following method.

Again the moving mass is seen as a rigid body. If he's not rigid If the calculation is sufficiently quick, it can in any case be called "locally rigid" be adopted, so that the method described also in these cases is applicable.  

First, the actuator forces F₁, F₂,. . ., F _m with

used to determine the forces and torques acting on the body men. The matrix X is made from the already determined angles of rotation and the translation vector with the context

calculated.

Using the least squares method or comparable methods Mass and center of gravity from the equation

be determined. An identification run or a sufficient number can be used for this Excitation using degrees of freedom can be used. In many cases you can M and also components of S without stimulation (in the rest position) of the body be determined.

If M and S are now known, the missing sizes A, B and C can be derived from the equation already given above

be determined. Again, the least squares method can be used or a comparable method can be used. Furthermore, there is a solution of the resulting quadratic system of equations Orthogonalization (e.g. according to Jacobi) required. Just like in the above Process step S31 described is recommended for orthogonalization an iterative process by using few or only one iteration step with starting values from the previous results.

The determination of A, B and C sets a rotational excitation in all three Degrees of rotation ahead. This can be done in an identification run or at corresponding high-dimensional suggestion happen online. Note that in the case of suggestions with z. B. only one degree of rotational freedom A degree of freedom of A, B and C is required for regulation. To this Way, if not all six degrees of freedom are required for movement, the method can be simplified to a low-dimensional method.

It has been shown that the above transformation is also performed in real time is feasible. In applications where identification runs are not allowed, can therefore also determine the dynamic characteristic values of the load online are assumed by initially plausible initial values and under continue ongoing execution of process steps S34 to S37 to the actual Values are introduced.  

The described transducer 10 not only works very quickly, but also very precisely, since all the kinematic actual values and the actuator forces are recorded and used (in this example in each case in eight dimensions), since the output variables (with six or ten degrees of freedom) are omitted a linearization can be calculated from the equations of motion and since only a few or even just one iteration is carried out in each step. As far as minor errors occur, they can easily be taken into account. For example, deviations of the test object from an ideal ellipsoid of inertia can be simulated by changes in the time of the main axes of inertia and the associated moments of inertia.

The transducer 10 leads the dynamic parameters obtained, namely the mass M of the load, the location S of its center of gravity and the main axes of inertia or main axes of the load with the associated moments of inertia to the setpoint transducer 5 (step S38), in which they step S22 to exact control of the drive controls 4 or the actuators 2 , 3 can be used, as described above. The determined quantities M and S can also be output at B to a system controller (not shown in FIG. 1) or to an operator.

In addition to the measured value converter 10 , the system of FIG. 1 contains a further measured value converter 11 which only receives the cylinder pressure differences Δp which are obtained from the pressure sensors 9 . The transducer 11 determines the simulated actual paths, actual speeds and Act accelerations of the load 1 in six degrees of freedom solely from the forces acting on the load 1 F₁, F₂,. . ., F₈, which result from the cylinder pressure differences Δp. The measured value converter 11 begins with any known spatial position in which excitation of the load 1 is to begin (method step S41, FIG. 4). Then cyclically new positions are determined by determining the acting forces and torques (method step S42), determining the accelerations of the load 1 (method step S43), integrating the speeds of the load 1 (method step S44) and using further integration the new movement coordinates of the load 1 are determined (method step S45), with which method step S42 starts again.

At C, the current movement, speed and acceleration values of the load 1 are fed to a monitoring circuit, not shown in FIG. 1, which performs an emergency shutdown of the system when certain permissible limit values are exceeded.

The calculations in the transducer 11 are carried out in detail according to the method described below.

Assuming that the load 1 represents a solid body with ten independent degrees of freedom, the forces and torques acting on the body are first determined.

According to the definitions and explanations given above, there are forces and torques on the one hand and the actuator forces F₁, F₂,. . ., F _m the linear relationship

with a matrix X ∈ R ^6xm , which results from the spatial coordinates

P₁ (t), P₂ (t),. . ., P _m (t)

of the m actuators on the moving body and

Q₁, Q₂,. . ., Q _m

calculated. The latter are constants of the system, while for P₁, P₂,. . ., P _m those values are used that were determined in the previous step.

The forces and torques are thus calculated. Again using rotation angles α _x , α _y , α _z and the translation vector (T _x , T _y , T _z ) from the previous step, the equation already given above becomes

used to determine the acceleration of the rotation angle. Since the second derivative of the rotation matrix (α _x , α _y , α _z ) is thus also known, it can be derived from the equation

the acceleration vector

be determined.

Now the aforementioned two-fold integration can be carried out, see above that now the movement coordinates, speeds and accelerations  are known to the body regarding translation and rotation.

To P₁ (t), P₂ (t),. . . To determine P _m (t), the vectorial movement of the points of attack of the actuators becomes too

certainly. This concludes the description of the calculation methods in the transducer 11 . It should also be noted that the required quantities M, S, A, B and C can be obtained by separate measurements or model calculations, but also automatically by the transducer 10 , as described above.

The following information can also be helpful for the practical implementation of the setpoint converter 5 and the measured value converter 10 or 11 . It can be of great advantage to replace the rotation angle with the sine function of the angle. A rotation description that deviates from the (3,2,1) -Euler representation can also be advantageous. Furthermore, a modification of the order of translation and rotation can be advantageous. Furthermore, the methods described can also be used for restricted movements, e.g. B. for five degrees of freedom of the moving load. In this case, the calculation can be simplified accordingly. Fast computing systems are required to perform the calculations online. The following may serve as a guide for a cycle time of 0.5 ms (MIPS - Mega Instructions Per Second): 200 MIPS for the setpoint converter 5 , 600 MIPS for the calculation of the kinematic actual values and 200 MIPS for the calculation of the dynamic parameters in the measured value converter 10 and 400 MIPS for the transducer 11 . Corresponding computing systems are readily available on the market. Instead of using universal computers, the setpoint converter 5 and the measured value converters 10 and 11 can of course also be implemented in hardware.

When applying the invention to given test benches, it should be noted that the transformations between the different dimensions in the setpoint converter 5 and in the measured value converters 10 and 11 may not lead to unambiguous solutions, a phenomenon which has already been observed in another context without understand its cause. This is because the determinant of the matrices used in the mathematical operations may become zero. This can be the case in particular with some arrangements of the actuators and sensors which have been preferred up to now for constructional reasons. Therefore, contrary to the previous practice, the matrix operations necessary for operation must be examined in the design phase of test benches and the like, under which circumstances determinants can become zero. If necessary, the actuator or sensor arrangement must be suitably changed.

Claims (25)

1.Control for drives of a load that is movable in several spatial dimensions, whereby several actuators acting in one dimension are coupled to the load in different directions and / or at different points and are controlled by an electronic drive control, the kinematic setpoints and force or torque setpoints for receives the actuator, characterized in that the drive controls ( 4 ) or at least two of the drive controls are connected together to a setpoint converter ( 5 ) which receives kinematic setpoints in a coordinate system and the

• a) converts the kinematic setpoints for the load ( 1 ) on the basis of the geometric arrangement of the actuators ( 2 , 3 ) into the corresponding kinematic setpoints for the connected actuators and
• b) using predetermined parameters of the load, which essentially describe the dynamic properties of the load as a rigid body, determines force and / or torque setpoints for the load and converts them into the corresponding force or torque setpoints for the connected actuators.

2. Control according to claim 1, characterized in that the kinematic Setpoints for the load paths, speeds and accelerations include. 3. Control according to claim 1 or 2, characterized in that the kinematic setpoints for load angles, angular velocities and Include angular accelerations. 4. Control according to one of the preceding claims, characterized in that one or more of the actuators are linear actuators ( 2 , 3 ) and that the kinematic setpoints for these actuators are distances, speeds and accelerations. 5. Control according to one of the preceding claims, characterized records that one or more of the actuators are rotary actuators and that the kinematic setpoints for these actuators angle, angular velocity speeds and angular accelerations. 6. Control according to one of the preceding claims, characterized in that the actuators comprise hydraulic actuators ( 2 , 3 ). 7. Control according to one of the preceding claims, characterized records that the actuators include electromechanical actuators. 8. Control according to one of the preceding claims, characterized in that the predetermined parameters of the load ( 1 ), which describe the dynamic properties of the load as a rigid body essentially completely, the mass of the load, the location of its center of gravity and the main axes of inertia of the load with the associated moments of inertia in the coordinate system. 9. Control according to one of the preceding claims, characterized in that the force or torque setpoints for the connected actuators ( 2 , 3 ) are determined in such a way that the sum of the squares of all forces or torques generated by the actuators applied to the load becomes minimal. 10. Control according to one of the preceding claims, characterized in that the actuators form a plurality of essentially identically constructed groups of at least two actuators ( 2 , 3 ) and that a plurality of substantially identical setpoint converters ( 5 ) are provided, each of the drive controls ( 4 ) control one of the groups of actuators. 11. Control according to one of claims 1 to 10, characterized in that eight mutually independent actuators are provided and that the kinematic setpoints for the load ( 1 ) are each six-dimensional quantities. 12. Measuring system for a load moving in several spatial dimensions, to which several one-dimensionally acting actuators are coupled in different directions and / or at different points, which are provided with adjusting sensors, characterized in that the measuring system furthermore several speed sensors ( 7 ) and Acceleration sensors ( 8 ), which sense the speeds or accelerations of the load ( 1 ) at different points and the number of which is at least equal to the number of degrees of freedom of the load, and comprises a transducer ( 10 ) which transmits the signals of the displacement sensors ( 6 ), the speed sensors ( 7 ) and the acceleration sensors ( 8 ) receives and converts them into kinematic actual values for the load in a coordinate system without linearization. 13. Measuring system according to claim 12, characterized in that a force sensor ( 9 ) is further provided on each actuator and that the transducer ( 10 ) using the obtained kinematic actual values of the load and the signals of the force sensors generates signals which reflect the dynamic properties of the Describe the load as a rigid body essentially completely in a coordinate system. 14. Measuring system according to claim 13, characterized in that the signals which essentially defines the dynamic properties of the load as a rigid body fully describe the mass of the load, the location of its center of gravity and the main axes of inertia of the load with the associated moments of inertia are in the coordinate system. 15. Measuring system according to one of claims 12 to 14, characterized in that that the kinematic actual values for the load paths, speeds and Accelerations include. 16. Measuring system according to one of claims 12 to 15, characterized in that the kinematic actual values for the load angle, angular velocities and include angular accelerations. 17. Measuring system according to one of claims 12 to 16, characterized in that that it is for a control according to one of claims 1 to 10 for determination of the parameters of the load is used, which is the dynamic eigen describe the load as a rigid body essentially completely. 18. Measuring system according to one of claims 12 to 17, characterized in that that it for regulating a control according to one of claims 1 to 10 in Agreement with the actual kinematic values for the load is used. 19. Measuring system according to one of claims 12 to 18, characterized in that the actuators are hydraulic actuators ( 2 , 3 ) and that the force sensors are pressure sensors ( 9 ). 20.Measuring system for a load moving in several spatial dimensions, to which a plurality of actuators acting one-dimensionally are coupled in different directions and / or at different locations, which are provided with force sensors, characterized by a transducer ( 10 ) which detects the signals of the force sensors ( 6 ) receives and converts them into kinematic actual values for the load in a coordinate system without linearization. 21. Measuring system according to claim 20, characterized in that the Kinematic actual values for the load paths, speeds and Accelerations include. 22. Measuring system according to claim 20 or 21, characterized in that the Actual kinematic values for the load angle, angular velocity and Include angular accelerations. 23. Measuring system according to one of claims 20 to 22, characterized in that that it for regulating a control according to one of claims 1 to 10 in Agreement with the actual kinematic values for the load is used. 24. Measuring system according to one of claims 20 to 23, characterized in that the actuators are hydraulic actuators ( 2 , 3 ) and that the force sensors are pressure sensors ( 9 ). 25. Measuring system according to one of claims 12 to 24, characterized in that eight mutually independent actuators are provided and that the kinematic actual values for the load ( 1 ) are each six-dimensional quantities.