JP5995561B2 - Test equipment - Google Patents

Description

  The present invention performs various tests such as a load test by applying an external force to a structure to be tested such as a shock absorber of a vehicle such as an automobile, a structure such as a building such as a bridge, a building, and a house. It relates to a test apparatus for performing.

  Conventionally, as a test apparatus of this type, a test apparatus 100 having a structure as shown in FIG. 6 has been proposed in order to test an object to be tested, for example, a shock absorber of a vehicle such as an automobile.

  That is, as shown in FIG. 6, the conventional test apparatus 100 includes a test apparatus main body 102 for performing a test. In this embodiment, the test apparatus main body 102 is composed of a vibration apparatus as an example of a test.

  As shown in FIG. 6, the test apparatus main body 102 includes a gantry frame 104, and an actuator 106 formed of a cylinder is provided below the gantry frame 104. The actuator 106 includes a piston 108 for loading the test piece A and a displacement detector 110 for detecting displacement.

  Further, an upper frame 118 is provided above the gantry frame 104, and a guide rod 112 is provided between the upper frame 118 and the gantry frame 104 in the upper frame 118.

  A ball screw 114 is provided between the lower portion of the guide rod 112 and the upper frame 118, and a cross head 116 that can be moved up and down with respect to the piston 108 by the ball screw 114 is provided. The cross head 116 is provided with a load detector 120 so as to face the piston 108.

  In the test apparatus 100 configured as described above, the test is performed as follows.

  That is, as shown in FIG. 6, a test piece A such as a shock absorber is loaded on the upper surface of the piston 108, and the crosshead 116 is lowered with respect to the piston 108 by the ball screw 114 by a driving mechanism (not shown). Then, the test piece A is sandwiched between the upper surface of the piston 108 and the lower surface of the cross head 116.

  Based on a program stored in advance in a control device (not shown), setting of test conditions and the like, execution of tests, and collection of test data are performed.

  That is, as shown in FIG. 6, an actuator power source (not shown) connected to the control device is driven under a predetermined condition by the control of the control device. As a result, the actuator 106 connected to the actuator power source is driven under a predetermined condition to give a constant vibration to the test piece A.

  The displacement of the test piece A is detected by a displacement detector 110 provided in the actuator 106, and the displacement data of the test piece A is input to the control device. On the other hand, a load applied to the test piece A is detected by a load detector 120 provided on the crosshead 116, and load data applied to the test piece A is input to the control device.

  Further, based on these test data, based on a program of the control device, a feedback command signal is output from the control device to the actuator power source, and the actuator 106 is driven under a predetermined condition.

Japanese Patent Application Laid-Open No. 11-173954

  Conventionally, in such a test apparatus 100, when amplitude control is performed, data for one cycle is stored in a memory, and when the excitation cycle is reached, the data is analyzed to obtain the next amplitude command. The value was calculated from the analysis result and the value was output.

  That is, as shown in FIG. 7, for example, when amplitude control is performed, the next amplitude command value is calculated from the maximum value P1 and the minimum value P2 of the amplitude for one period.

  However, in such a control method, as shown in FIG. 8, in the periodic waveform test, it takes an excitation period, that is, one period or more to reach a preset amplitude P3. Become.

  As a result, when there is a temperature dependence, for example, a liquid such as oil filled in a shock absorber or the like, an extra load is applied to the test piece A. Due to the load during this time, a liquid such as oil or the like is applied. The viscosity of the test changed and the test results were affected, and accurate testing and analysis were not possible. Therefore, it has been conventionally required to shorten the arrival time of the set amplitude.

  In addition, for example, in a seismic waveform reproduction test, in a control waveform generation process, a conventional test apparatus uses a test piece or a dummy test piece to perform a preliminary test and acquire data, and based on this data, a control waveform Need to form. For this reason, the preliminary test for controlling for every sample was required, the test cost was high, test efficiency was bad, and it was a waste of resources.

  In view of such a current situation, the present invention can shorten the arrival time of the set amplitude. For example, the test can be performed even when there is temperature dependency like a liquid such as oil filled in a shock absorber or the like. There is no extra load on the piece A, and the load during this time does not change the viscosity of the liquid such as oil and does not affect the test results, allowing accurate testing and accurate analysis. An object is to provide a test apparatus.

  Another object of the present invention is to provide a test apparatus that does not require a preliminary test for controlling each sample, can reduce test costs, has high test efficiency, and can efficiently use resources. And

The present invention was invented in order to achieve the problems and objects in the prior art as described above.
A test apparatus for performing various tests by applying an external force to a structure under test,
Using a digital controller, measure the input / output characteristics for each sample, calculate the impulse response from the measured values,
The impulse response calculation result is fed back to the control as the identification value of the structure under test to be controlled, and the impulse response control is performed.
Using the digital controller, the following equation:
Y (t) = H (t) · X (t)
Here, X (t) is an input value, Y (t) is an output value, and H (t) is a transfer function of the digital controller.
Is used to find the transfer function H (t),
Based on the next target value R, the following equation:
From R = H · X, the next input value X is
Calculate from X = R / H,
The next output value Y is
The impulse response control is performed by calculating from Y = R.

  With this configuration, the input / output characteristics for each sample are measured using the digital controller, and the impulse response is calculated from the obtained measurement values. Then, this calculation result is fed back to the control as an identification value of the structure under test that is a control target.

  Therefore, it is possible to carry out control for an arbitrary set amplitude without measuring for the excitation period.

  Thereby, the arrival time of the set amplitude can be shortened. For example, even when the temperature depends on the liquid such as oil filled in the shock absorber or the like, an extra load is applied to the test piece A. In addition, the load during this time does not change the viscosity of the liquid such as oil and affects the test result, and it is possible to perform an accurate test and an accurate analysis.

  In addition, the present invention can provide a test apparatus that does not require a preliminary test for performing control for each sample, can reduce test costs, has high test efficiency, and can efficiently use resources. .

  In addition to controlling the amplitude of the low-frequency excitation test, the input / output characteristics can be measured for each sample and the excitation waveform can follow the target waveform for each sample. The rate can be improved, and accurate testing and accurate analysis can be performed.

In addition, the test apparatus of the present invention is
The digital controller is
An impulse response calculation processing unit for processing input values;
It is comprised from the PID controller which performs a digital process based on the input from the said impulse response calculation process part, It is characterized by the above-mentioned.

  As described above, it is desirable that the digital controller includes an impulse response calculation processing unit that processes an input value and a PID controller that performs digital processing based on an input from the impulse response calculation processing unit.

  In the test apparatus according to the present invention, the impulse response calculation processing unit includes a variable weight for correcting an input value and an impulse response calculation processor.

  As described above, it is desirable that the impulse response calculation processing unit includes the variable weight for correcting the input value and the impulse response calculation processor.

In addition, the test apparatus of the present invention is
According to the command value output from the PID controller, the sensor signal from the structure under test is divided into the following three systems (1) to (3), that is,
(1) feedback to the feedback gain of the PID controller;
(2) feedback to the impulse response calculator;
(3) feedback to the variable weight;
It is comprised so that it may carry out.

  By configuring in this way, the above-described effects can be achieved.

In addition, the test apparatus of the present invention is
In the next control sampling, the previous input value is input to the impulse response calculator,
When the control command value calculated by the impulse response calculation processor is input to the PID controller, the feedback of the sensor signal from the structure under test to the variable weight is monitored with the variable weight, and the control command The configuration is such that the value is corrected and input to the PID controller.

  By configuring in this way, it is possible to prevent divergence due to non-linear factors and to realize target tracking with high accuracy.

  According to the present invention, an input / output characteristic for each sample is measured using a digital controller, and an impulse response is calculated from the obtained measurement value. Then, this calculation result is fed back to the control as an identification value of the structure under test that is a control target.

  Therefore, it is possible to carry out control for an arbitrary set amplitude without measuring for the excitation period.

  Thereby, the arrival time of the set amplitude can be shortened. For example, even when the temperature depends on the liquid such as oil filled in the shock absorber or the like, an extra load is applied to the test piece A. In addition, the load during this time does not change the viscosity of the liquid such as oil and affects the test result, and it is possible to perform an accurate test and an accurate analysis.

  In addition, the present invention can provide a test apparatus that does not require a preliminary test for performing control for each sample, can reduce test costs, has high test efficiency, and can efficiently use resources. .

  In addition to controlling the amplitude of the low-frequency excitation test, the input / output characteristics can be measured for each sample and the excitation waveform can follow the target waveform for each sample. The rate can be improved, and accurate testing and accurate analysis can be performed.

FIG. 1 is a schematic view showing an embodiment in which the test apparatus of the present invention is applied to an excitation test apparatus that performs an excitation test as an example of a test. FIG. 2 is a front view for explaining a use state of the test apparatus main body of FIG. FIG. 3 is a schematic diagram showing a control method of the test apparatus of the present invention. FIG. 4 is a block diagram showing a method for controlling the test apparatus of the present invention. FIG. 5 is a graph showing a control method of the test apparatus of the present invention. FIG. 6 is a front view of a conventional test apparatus 100. FIG. 7 is a graph showing a control method of the conventional test apparatus 100. FIG. 8 is a graph showing a control method of the conventional test apparatus 100.

  Hereinafter, embodiments (examples) of the present invention will be described in more detail with reference to the drawings.

  FIG. 1 is a schematic diagram showing an embodiment in which the test apparatus of the present invention is applied to an excitation test apparatus for performing an excitation test as an example of a test, and FIG. 2 illustrates a use state of the test apparatus main body of FIG. FIG. 3 is a schematic view showing a control method of the test apparatus of the present invention, FIG. 4 is a block diagram showing a control method of the test apparatus of the present invention, and FIG. 5 is a control method of the test apparatus of the present invention. It is a graph which shows.

  In FIG. 1, the code | symbol 10 has shown the test apparatus of this invention on the whole.

  As shown in FIGS. 1 to 2, the test apparatus 10 of the present invention includes a test apparatus main body 12 for performing a test. In this embodiment, the test apparatus main body 12 is composed of a vibration test apparatus that performs a vibration test as an example of a test.

  As shown in FIG. 1, the test apparatus main body 12 includes a gantry frame 14, and an actuator 16 including a cylinder is provided below the gantry frame 14. The actuator 16 includes, for example, a piston 18 for loading a test piece A such as a shock absorber of a vehicle such as an automobile, and a displacement detector 20 for detecting displacement.

  Further, an upper frame 28 is provided above the gantry frame 14, and a guide rod 22 is provided between the upper frame 28 and the gantry frame 14 in the upper frame 28.

  A ball screw 24 is provided between the lower side of the guide rod 22 and the upper frame 28, and a cross head 26 that is movable up and down with respect to the piston 18 by the ball screw 24 is provided. The crosshead 26 is provided with a load detector 30 so as to face the piston 18.

  Further, as shown in FIG. 1, the test apparatus 10 of the present invention is connected to the test apparatus main body 12, and for the test apparatus main body 12, setting of test conditions and the like, execution of tests, collection of test data, etc. A control device 32 is provided which functions as a test control device for performing.

  In this embodiment, the control device 32 includes a CRT 34 for displaying a setting screen for test conditions, test data, and the like, a control device main body 36, a keyboard 38, and a mouse 40. Therefore, the control device 32 has an internal memory composed of, for example, a hard disk. An operation personal computer may be connected to the control device main body 36.

  The displacement detector 20 of the actuator 16 of the test apparatus main body 12 and the control apparatus main body 36 are connected, and the load detector 30 of the test apparatus main body 12 and the control apparatus main body 36 are connected.

  On the other hand, in the test apparatus 10 of the present invention, an actuator power source 44 connected to the control device main body 36 of the control device 32 and connected to the actuator 16 of the test device main body 12 is provided.

  In the test apparatus 10 of the present invention configured as described above, the test is performed as follows.

  That is, as shown in FIG. 2, the test piece A is loaded on the upper surface of the piston 18, and the crosshead 26 is lowered with respect to the piston 18 by the ball screw 24 by a driving mechanism (not shown). And the test piece A is sandwiched between the lower surface of the cross head 26.

  Then, based on a program stored in advance in the control device 32, setting of test conditions and the like, execution of tests, and collection of test data are performed.

  That is, as shown in FIG. 1, the actuator power source 44 connected to the control device 32 is driven under a predetermined condition by the control of the control device 32. As a result, the actuator 16 connected to the actuator power source 44 is driven under a predetermined condition to give a constant vibration to the test piece A.

  A displacement detector 20 provided in the actuator 16 detects the displacement of the test piece A, and the displacement data of the test piece A is input to the control device main body 36 of the control device 32. On the other hand, the load applied to the test piece A is detected by the load detector 30 provided in the cross head 26, and the load data applied to the test piece A is input to the control device main body 36 of the control device 32. Yes.

  Further, based on these test data, based on the program of the control device main body 36 of the control device 32, a feedback command signal is output from the control device 32 to the actuator power source 44, and the actuator power source 44 is set under a predetermined condition. It is designed to drive.

  By the way, in the test apparatus 10 of the present invention, the controller 32 is configured to perform the following control.

  That is, the test apparatus 10 of the present invention includes the digital controller 50 as shown in FIG. 3 in the control device main body 36 of the control device 32.

  Using this digital controller 50, the input / output characteristics for each sample are measured, and the impulse response is calculated from the obtained measurement values. The impulse response calculation result is fed back to the control as an identification value of the structure to be tested as a control target to perform impulse response control.

  Specifically, control is performed by the control method described with the graph shown in FIG.

That is, as shown in FIG. 3, using the digital controller 50, the following equation:
Y (t) = H (t) · X (t)
Here, X (t) is an input value, Y (t) is an output value, and H (t) is a transfer function of the digital controller 50.

  Using this equation, for example, the transfer function H (t) is obtained from X (t1) and Y (t1) in the graph of FIG.

Then, based on the next target value R, the following equation:
From R = H · X, the next input value X (for example, X (t2) in the graph of FIG. 5)
Calculate from X = R / H,
The next output value Y (for example, Y (t2) in the graph of FIG. 5) is
The impulse response control is performed by calculating from Y = R.

  More specifically, the calculation is performed as follows.

That is, when the input of the digital controller 50 is x (n) and the output is y (n) and Z conversion is performed, the input x (z)
x (z) = x ₀ + x ₁ z ⁻¹ + x ₂ z ⁻² +... x _n−1 z ^{−n + 1}
It is.

The transfer function H of the digital controller 50 is
H (z) = h ₀ + h ₁ z ⁻¹ + h ₂ z ⁻² +... H _n−1 z ^{−n + 1}
Can be expressed as Therefore,
Y (z) = H (z) · X (z)
It becomes.

  Here, the system is a system in which the input is X (z), the output is Y (z), and the transfer function is H (z).

  Actually, an error signal is output and added to this system, so that the following equation is obtained.

y (n) = h (n) .x (n) + e (n)
e (n) = d (n) -y (n)

  Here, d (n) is a signal to be a target (ideal).

This e (n) can be expressed by the following equation.

w = [h ₀ h ₁ ... h _T-1 ] ^T

x (n) = [x (n), x (n-1)... x (n-I + 1)] ^T

  Here, since the coefficient of the digital controller 50 that minimizes the error may be obtained, the following expression is developed with J as the optimum filter coefficient.

J = E [e ² (n)]
Here, E is an expected value operator.

Using the above equation (2),
J = w ^T Aw-2w ^T b + c

here,
^{A = E [x (n)} x T (n)]
b = E [x (n) d (x)]
c = E [d ² (n)]

  A is a Hessian matrix,

Here, R _xx is an autocorrelation function of x (n).

  Using the above equation (1), the error equation is expressed as follows:

  If J is invariant with time,

Furthermore, assuming that the signal is a stable (stationary) signal, the autocorrelation and the correlation function are
_{R xx (m) = E [} x (n + m) x T (n)]
R _xd (m) = E [d (n + m) x ^T (n)]
R _dd (m) = E [x (n + m) d ^T (n)]

here,
R ^T _xx (m) = R _xx (−m)
W = [w ₀ w ₁ ... W _l−1 ] ^T
R _xd = [R _xd (0) R _x d (1)... R _xd (i-1)] ^T
R ^T _xx = R _xx
Then, the above equation (3) becomes

E [e (n) e ^T (n)] = w ^T R _xxw −w ^T R _xd −R _xd ^T w−R _dd (0)

  Applying the nature of the trace matrix,

Then,
R _xx w _opt = R _xd
Here, w _opt is where the slope is 0 and the error is minimum. Therefore,
w _opt = R _xx ⁻¹ · R _xd
It becomes the system of the optimal digital system. Using this,

D (z) = w _opt · x (z) (4)
Then, the input signal is obtained.

However, in reality, there is a risk of divergence only by this equation (4) due to the influence of disturbances and the like. Therefore,
C ₁ = D (z) −Y (z)

The constant based on any data table, according to the rules in the above formula (5), sets the correction coefficient C _2. That is,

Y (z) = H · X (Z) + C ₂ (6)

Here, H is H obtained by adding controller parameters in addition to w _opt .
Control is performed according to the equation (6).

  More specifically, the test apparatus 10 of the present invention includes a digital controller 50 as shown in FIG. 4 in the control device main body 36 of the control device 32.

  As shown in the block diagram of FIG. 4, the digital controller 50 includes an impulse response calculation processing unit 52 that processes an input value, and a PID controller 54 that performs digital processing based on an input from the impulse response calculation processing unit 52. It consists of and. The impulse response calculation processing unit 52 includes a variable weight 56 that corrects an input value and an impulse response calculation processor 58.

  In the digital controller 50 configured as described above, digital control is performed as follows.

  First, an input signal from the input 60 is input to the PID controller 54 via the variable weight 56 of the impulse response calculation processing unit 52. Then, digital calculation is performed by the proportional gain Kp, the integral gain Ki, and the differential gain Kd in the PID controller 54, and the command value is output to the test apparatus main body 12 that is the control target via the output signal Kout.

  Then, the test is performed in the test apparatus main body 12, and the sensor signals from the displacement detector 20 and the load detector 30 from the test piece A which is a specimen are divided into the following three systems (1) to (3). And is fed back.

That is, the sensor signal from the test piece A which is a specimen is
(1) Feedback is made to the feedback gain Kfb of the PID controller 54.
(2) Feedback is made to the impulse response calculator 58 of the impulse response calculator 52.
(3) Feedback is made to the variable weight 56 of the impulse response calculation processing unit 52.
In this way, the sensor signal is fed back by being divided into three systems.

Then, in the next control sampling, the previous input value Z ⁻¹ is input to the impulse response calculation processor 58 of the impulse response calculation processing unit 52.

  Further, when the control command value calculated by the impulse response calculation processor 58 is input to the PID controller 54, the feedback of the sensor signal from the test piece A, which is the structure under test, to the variable weight 56 is changed to the variable weight. Monitoring is performed at 56, and the control command value is corrected and input to the PID controller 54.

  With this configuration, the digital control described above is performed. In addition, divergence due to non-linear factors can be prevented, and highly accurate target tracking can be realized.

  The preferred embodiment of the present invention has been described above. However, the present invention is not limited to this, and the test apparatus 10 according to the present invention can be used as a test apparatus, for example, an automobile component (such as a drive system or undercarriage). Metal parts, rubber parts, shock absorbers, etc.), finished automobiles, etc., and civil engineering-related structures (bridge girder, bridges, seismic isolation rubber for buildings, etc.) It can be applied to various testing devices such as a material testing device, a vibration testing device, a fatigue testing device for performing a test, a vibration test, a fatigue test, a characteristic test, etc. Can be changed.

The present invention performs various tests such as a load test by applying an external force to a structure to be tested such as a shock absorber of a vehicle such as an automobile, a structure such as a building such as a bridge, a building, and a house. It can be applied to a test apparatus for performing.

DESCRIPTION OF SYMBOLS 10 Test apparatus 12 Test apparatus main body 14 Mounting frame 16 Actuator 18 Piston 20 Displacement detector 22 Guide rod 24 Ball screw 26 Crosshead 28 Upper frame 30 Load detector 32 Controller 36 Controller main body 38 Keyboard 40 Mouse 44 Actuator power source 50 Digital Controller 52 Impulse response calculation processor 54 PID controller 56 Variable weight 58 Impulse response calculation processor 60 Input 100 Test device 102 Test device body 104 Mounting frame 106 Actuator 108 Piston 110 Displacement detector 112 Guide rod 114 Ball screw 116 Crosshead 118 Upper frame 120 Load detector

A Test piece (structure under test)

Claims (5)

A test apparatus for performing various tests by applying an external force to a structure under test,
Using a digital controller, measure the input / output characteristics for each sample, calculate the impulse response from the measured values,
The impulse response calculation result is fed back to the control as the identification value of the structure under test to be controlled, and the impulse response control is performed.
Using the digital controller, the following equation:
Y (t) = H (t) · X (t)
Here, X (t) is an input value, Y (t) is an output value, and H (t) is a transfer function of the digital controller.
Is used to find the transfer function H (t),
Based on the next target value R, the following equation:
From R = H · X, the next input value X is
Calculate from X = R / H,
The next output value Y is
A test apparatus that performs impulse response control by calculating from Y = R. The digital controller is
An impulse response calculation processing unit for processing input values;
The test apparatus according to claim 1 , further comprising a PID controller that performs digital processing based on an input from the impulse response calculation processing unit. The test apparatus according to claim 2 , wherein the impulse response calculation processing unit includes a variable weight for correcting an input value and an impulse response calculation processor. According to the command value output from the PID controller, the sensor signal from the structure under test is divided into the following three systems (1) to (3), that is,
(1) feedback to the feedback gain of the PID controller;
(2) feedback to the impulse response calculator;
(3) feedback to the variable weight;
The test apparatus according to claim 3 , wherein the test apparatus is configured to perform the test. In the next control sampling, the previous input value is input to the impulse response calculator,
When the control command value calculated by the impulse response calculation processor is input to the PID controller, the feedback of the sensor signal from the structure under test to the variable weight is monitored with the variable weight, and the control command The test apparatus according to claim 3 , wherein the test apparatus is configured to correct the value and input the corrected value to the PID controller.

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