JP4304825B2 - Vibration control system - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a vibration damping system for damping minute vibrations of a device in a factory or the like where various vibration damping devices are installed.
[0002]
[Prior art]
As is well known, in a semiconductor factory, a precision machine factory, etc., devices that dislike various vibrations such as an electron microscope, an exposure device, and a measuring device are installed in a wide area. For this reason, some vibration control measures are required for these devices themselves or the floors, beams, buildings, etc. on which the devices are installed.
[0003]
On the other hand, conventionally, as means for damping vibrations of floors in various structures, a method of attaching a damping device using an energy absorbing damper such as an oil damper or a viscous damper to a frame such as a large beam, the above floor, etc. A method of installing a TMD (Tuned Mass Damper) set to a weight according to the natural frequency of the above on the floor has been put into practical use.
[0004]
[Problems to be solved by the invention]
However, although all of the above conventional vibration damping devices can exhibit a vibration damping effect against vibrations having a relatively large amplitude, mechanical loss due to device backlash or friction is large, It cannot be expected to have a damping effect on mechanical vibrations of several μm level generated in a semiconductor factory as described above, or micro vibrations such as environmental vibrations, and thus cannot be applied as a vibration damping device for the vibration isolator. There was a problem.
[0005]
In addition, in recent years, particularly in semiconductor factories, there are an increasing number of cases where multilayers and long spans are achieved. For this reason, the natural frequency of the floor is as soft as several Hz, and as a result, it is very easy to shake. In addition, due to the high performance of manufacturing / inspection equipment, more stringent vibration tolerances are required for these installation environments.
[0006]
Therefore, in the case of performing fine vibration suppression for this type of vibration isolator, as shown in FIG. 9, a vibration isolator or the like is provided between the support surface 50 such as the floor and the individual vibration isolator 51. A method of interposing a vibration isolator 52 such as an active vibration isolator is employed. Here, the active vibration isolation device is a device that suppresses the response at the resonance frequency by an actuator incorporated in the vibration isolation device.
[0007]
According to the vibration damping method using the vibration isolation device 52 such as the vibration isolation device or the active vibration isolation device, a one-mass system vibration system is configured with the vibration isolation device 51 as a weight and the vibration isolation device 52 as a spring. Therefore, it is possible to reduce the response to vibration input components other than the natural frequency of each one-mass system.
[0008]
However, since the conventional vibration isolator 52 needs to be installed for each vibration isolator 51, it should be applied to a place where many vibration isolators 51 such as the semiconductor factory are installed. Then, the number of vibration isolation devices 52 such as the required vibration isolation devices and active vibration isolation devices becomes large, and as a result, there is a problem that the equipment cost is increased.
[0009]
The present invention has been made in view of the above circumstances, and can exhibit an excellent vibration damping effect even for vibrations of minute amplitudes that could not be realized by conventional vibration damping devices and the like, and is installed on the floor. Accordingly, an object of the present invention is to provide a vibration suppression system that can perform vibration suppression for a plurality of vibration isolation devices and is excellent in economic efficiency.
[0010]
[Means for Solving the Problems]
The active vibration damping device according to the first aspect of the present invention includes a base attached to an object to be controlled, a support erected on the base, a drive coil supported on the upper end of the support, and the drive coil. A metal damper body that becomes a weight provided on the support column via a linear motion bearing, and an excitation coil that is provided in the damper body to excite the damper body, and the damper body An active vibration control device including an urging member that elastically supports the base plate or a control target, a controller that inputs a control force to the drive coil, and a frequency generated in the control target provided in the control target The active vibration damping device is set to a weight corresponding to the natural frequency of the control target, and the controller The natural frequency of the control object and the assumed specific frequency are set in advance, and a frequency weighting function for sensitivity reduction having a large weight at the specific frequency is set and controlled using the H-infinity control theory. The gain is designed .
[0011]
According to a second aspect of the present invention, there is provided a vibration damping system according to the first aspect of the present invention, wherein the controller includes the controller at a frequency other than the natural frequency of the control target and the specific frequency. A control gain designed using a robust stable frequency weighting function that reduces the sensitivity of the active vibration damping device is set .
[0012]
Here, in the vibration damping system according to claim 3, the control object on which the active vibration damping device according to claim 1 or 2 is installed is supported by a pillar as a structural floor for installing a vibration isolator. It is characterized by being a floor composed of a structured beam or slab.
[0014]
In the vibration damping system according to claim 1, the frequency of the control target modeled in advance in the controller is set, and the drive coil is excited at the frequency to control the vertical movement of the damper main body. The vibration of the controlled object at the above frequency is damped. At this time, according to the active vibration damping device, the damper main body moves up and down by driving the linear motor with respect to the support column, so that the frictional force is extremely small and the response is excellent. For this reason, it is possible to effectively exhibit a damping effect even for a slight vibration of several μm level, which could hardly be expected with a conventional damping device.
[0015]
Furthermore , in addition to the vibration suppression control of the vibration caused by the natural frequency of the control target, the active vibration suppression device further detects the frequency due to the disturbance of the control target by the sensor, and based on the detection signal, in the controller The control design using the frequency weighting function for sensitivity reduction that has the largest weight in the frequency due to the disturbance of the controlled object using infinity control theory is used, so the active vibration suppressor is set to the frequency due to the set disturbance. Even if the vibration of the band is effectively activated to generate a damping force for the vibration, even if the natural frequency of the controlled object does not match the frequency of the disturbance, the vibration due to the disturbance is effectively prevented. Can be reduced. As a result, even if the device is light and small, high vibration damping performance can be obtained.
[0016]
Furthermore, according to the invention described in claim 3, since the active vibration damping device is installed on a floor composed of a beam or a slab supported by a pillar as a structural floor for installing a vibration isolator. With one active vibration control device, it is possible to simultaneously reduce input vibrations to a plurality of vibration isolation devices installed in a wide area. As a result, a significant cost reduction can be achieved as compared with a conventional vibration control system in which a vibration isolator is installed in each vibration isolator.
[0017]
In addition, as a result of being able to reduce the level of microvibration of the floor or the like, it is possible to achieve further long span and multi-layers, and increase the degree of freedom in design.
In addition, even when there are large structural plan constraints such as renewal factories of semiconductor factories, it is possible to reduce the level of micro vibrations such as floors. Is possible.
[0018]
Furthermore, in the invention according to claim 3, when the beam forms a continuous span, the primary mode of the beam of the continuous span is a uniform deformation mode in the entire span. In damping the primary frequency, this primary mode is controlled. For this reason, if the total weight of the active vibration control devices is equal, an equivalent vibration suppression effect can be obtained regardless of the number of installed devices and the position of the installation span.
[0019]
Therefore , if one active vibration control device having a weight multiple of the weight necessary to control the vibration of the natural primary frequency in one span is installed on the beam or floor over a plurality of spans, one unit The active vibration damping device can reduce the fluctuation of the natural primary frequency in the plurality of spans. As a result, the number of active vibration damping devices required is further reduced, thereby reducing costs and reducing resources. Can be achieved.
[0020]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, an embodiment of a vibration suppression system according to the present invention will be described with reference to the drawings.
FIG. 1 shows the active vibration damping device used in this vibration damping system, and reference numeral 1 in the figure denotes a rectangular plate-like base for mounting the device M on the floor. A metal support 2 having a predetermined strength is erected in the center of the base 1, and a metal damper body 7 having a predetermined weight is movably disposed around the support 2. Yes. Here, the damper main body 7 is provided so as to be movable in the vertical direction with respect to the support column 2 by interposing a linear motion ball bearing 3 between the core portion 4 and the support column 2.
[0021]
On the other hand, a cylindrical upper stopper 5 that restricts the upward displacement of the damper main body 7 by a top plate 5 a is integrally attached to the upper end portion of the support column 2, and the damper main body 7 is attached to the upper stopper 5. A drive coil 8 for controlling the movement is provided so as to be inserted into the outer periphery of the core portion 4 of the damper main body 7. And inside the damper main body 7, the exciting coil 6 is arrange | positioned through the slight clearance between the inner peripheral surface and the outer peripheral surface of the core part 4, and the damper main body 7 magnetizes magnetism by this exciting coil 6. It comes to be tinged.
[0022]
An annular plate-like flange portion 9 protruding like a bowl is fixed to the outer periphery of the damper main body 7, and a spring (for elastically supporting the damper main body 7 between the flange portion 9 and the base 1. (Biasing member) 10 is arranged at equal intervals at a plurality of locations in the circumferential direction. In the figure, reference numeral 11 denotes a lower stopper for the damper main body 7. Further, the active vibration damping device M is mounted with a controller (see FIG. 3) 12 for inputting a control force for controlling the driving of the damper body 7 using the H-infinity control theory.
[0023]
Next, an embodiment of the vibration damping system of the present invention using the active vibration damping device M having the above configuration will be described with reference to FIGS.
As shown in FIG. 2, the active vibration control device M is installed on a floor 15 composed of a beam or a slab supported by a pillar 14 on which a plurality of (three in the figure) vibration isolator 13 is installed. Yes. Further, the floor 15 is provided with a sensor (see FIG. 3) 16 for detecting the frequency generated in the floor 15 due to the disturbance W ₁ caused by an earthquake, wind, mechanical vibration or the like.
[0024]
FIG. 3 shows the control system 20 in the vibration damping system of the present embodiment. Reference numeral 21 in the figure denotes a floor (control target) on which the vibration damping device 13 is installed and the active vibration damping device M is installed. . Here, the active vibration control device M is configured to control the shape of the control target 21 obtained by modeling the shape, weight, number of installed vibration isolator 13, weight, installation position, and the like of the control target 21. The weight corresponding to the natural frequency is set, and by giving a control input to the drive coil 8, the operation of the damper body 7 is controlled to suppress the vibration generated in the controlled object 21. .
[0025]
Then, the controller 12 mounted on the active vibration damping device M inputs the control force to the active vibration damping device M, excites the drive coil 8 to freely move the damper main body 7 up and down, thereby causing the core portion 4 to move. The vibration of the controlled object 21 is attenuated using the inertial force due to the weight of the damper body 7 including
[0026]
Further, the controller 12 has a large weight in the disturbance frequency fb from the detection signal of the frequency fb of the controlled object 21 generated by the disturbance W ₁ other than the natural frequency fn detected by the sensor 16. There is provided a computer (arithmetic unit) for setting a control gain designed based on the H-infinity control theory by setting a frequency weighting function Ws for sensitivity reduction. Further, the controller 12 uses robust stable frequency weighting functions Wn and Wt that reduce the sensitivity of the active vibration damping device M at frequencies other than the natural frequency fn of the control target 21 and the assumed disturbance frequency fb in advance. The designed control gain is set.
Incidentally, reference numeral W ₂ shows the observation noise included like the sensor 16 and the amplifier.
[0027]
According to the vibration damping system using the active vibration damping device M having the above-described configuration, first, the frequency fb due to the disturbance W ₁ other than the natural frequency caused by the earthquake, mechanical vibration, or the like is controlled by the sensor 16 by the sensor 16. Is detected, the detection signal is sent to the controller 12, and as shown in FIG. 4, a frequency weighting function Ws for sensitivity reduction having a large weight at the disturbance frequency fb is set in advance, and the H infinite theory is set. Is multiplied by the control gain obtained by the design using.
[0028]
In the controller 12, a control force for reducing sensitivity based on the frequency weighting function Ws is input to the drive coil 8 of the active vibration damping device M installed in the control target 21. As a result, the vertical movement of the damper main body 7 is controlled and the vibration damping action as the active vibration damping device M is exhibited, whereby the vibration fb in the controlled object 21 is reduced.
[0029]
At this time, according to the control using only the frequency weighting function Ws for sensitivity reduction, a large control force is generated even in the frequency range other than the natural frequency fn to be controlled and the disturbance frequency fb. . Therefore, as described above, the controller 12 is set with robust stable frequency weighting functions Wt and Wn that reduce the sensitivity of the active vibration damping device M at frequencies other than the frequencies fn and fb to be controlled. Then, the controller 12 inputs the control force for sensitivity reduction based on the robust stable frequency weighting functions Wt and Wn to the active vibration damping device M using the H-infinity control theory, and controls the control target frequencies fn and fb. The operational stability of the active vibration control device M is ensured by reducing the sensitivity at frequencies other than.
[0030]
In the present embodiment, as shown in FIG. 5, as a robust stable frequency weighting function, a frequency weighting function Wt having a large weight in the high frequency region and a frequency weighting function Wn having a large weight in the low frequency region are used. By combining, the control force mainly in the high frequency region is suppressed by the frequency weighting function Wt, the control force mainly in the low frequency region is suppressed by the frequency weighting function Wn, and the drift suppression effect of the apparatus is exhibited. It is set.
[0031]
As described above, according to the active vibration damping device M, the natural frequency fn or disturbance frequency fb to be controlled that is modeled in advance in the controller 12 is set, and the drive coil is set at these specific frequencies fn or fb. By exciting 8, the vertical movement of the damper body 7 can be controlled to suppress the vibration of the controlled object 21 at the specific frequency fn or fb. At this time, according to the active vibration damping device M, the damper main body 7 moves up and down by driving the linear motor with respect to the support column 2, so that the frictional force is extremely small and the response is excellent. The vibration damping effect can be effectively exhibited even for a slight vibration of several μm level that could hardly be expected depending on the vibration damping device.
[0032]
FIG. 6 shows experimental results of measuring the floor displacement when the vibration damping device is not provided and when the active vibration damping device M is provided by the present inventors, and the vibration damping device is not provided. It can be seen that the displacement amount, which was 6.68 μm at the maximum, was greatly reduced to 2.57 μm by providing the active vibration damping device M.
[0033]
Further, according to the vibration damping system using the active vibration damping device M, in addition to the vibration damping control due to the natural frequency fn of the controlled object 21, the sensor 16 further causes the disturbance W ₁ of the controlled object 21. detects the frequency fb, based on this detection signal, the frequency weighting function Ws for reduced sensitivity with the highest weighting at a frequency fb by the disturbance W ₁ of the controlled object 21 using the H-infinity control theory in the controller 12 Since the active vibration damping device M is actuated against the vibration of the frequency band fb due to the set disturbance W ₁ to generate a damping force for the vibration, in the case where the frequency fb by the natural frequency fn and the disturbance W ₁ of the target 21 does not match it can also effectively reduce the shaking due to the disturbance W ₁ As a result, even if the device is light and small, high vibration damping performance can be obtained.
[0034]
In addition, since the robust stable frequency weighting functions Wt and Wn are set together with the frequency weighting function Ws, the generation of the control force in the frequency band other than the control target frequencies fn and fb can be suppressed. As a result, it is possible to improve the robustness of the active vibration damping device against the modeling error when setting the natural frequency fn described above, the phase delay of the control force input from the controller 4 to the actuator, and the like. Therefore, strong control at specific control target frequencies fn and fb can be realized.
[0035]
Furthermore, since the active vibration control device M is installed on the floor 15 on which a plurality of vibration isolation devices 13 are installed, a single active vibration suppression device M can simultaneously input vibration to these vibration isolation devices 13. Can be reduced. As a result, a significant cost reduction can be achieved as compared with the conventional vibration damping system in which the vibration isolator 52 is installed in each vibration isolator 51 shown in FIG. In addition, even when there are large structural plan constraints such as renewal factories of semiconductor factories, it is possible to reduce the level of micro vibrations such as floors. Is possible.
[0036]
In addition, as a result of being able to reduce the fine vibration level of the floor 15 or the like, it is possible to further increase the span or to increase the number of layers. As a result, the degree of freedom in design can be increased. That is, the active vibration control device M and the vibration control system using the same suppress the entire floor or a part of the floor so as to reduce the vibration and deformation of the large beam. Resource saving can be realized by designing the member small.
[0037]
For example, as shown in FIG. 7 (a), on the floor of a general semiconductor factory having a beam length of 90 cm and a span length of about 5.5 mm, as shown in FIG. When the vibration control device M is installed, the beam length can be reduced to about 2/3 of 60 cm with respect to the same span length of 5.5 m, and as shown in FIG. When the length is not changed from 90 cm, the span length can be increased to about 11.0 m, which is twice as long, and as a result, the number of pillars can be halved.
[0038]
Further, FIG. 8 (b) shows another embodiment of the vibration damping system according to the present invention. In the floor 25 on the beam over a plurality of spans (5 spans in the figure), the natural primary vibration in one span is shown. A single active vibration control device M having a weight five times the weight required to control several vibrations is installed. That is, the primary mode of the beam having a continuous span is a deformation mode in which all spans are uniform. Therefore, the primary mode is controlled in the vibration suppression of the natural primary frequency of the floor 25. For this reason, if the total weight of the active vibration control devices M is equal, the same vibration suppression effect can be obtained regardless of the number of installed units and the position of the installation span.
[0039]
For example, as shown in FIG. 8 (a), when the active vibration control device M is installed on the floor 25 of each span, the active vibration control device required to control the natural primary frequency in each span is used. If the weight is 50 kgf, the total weight of the active vibration control devices installed in one layer is 50 kgf × 5 units = 250 kgf.
Therefore, in the case shown in FIG. 8B, an equivalent vibration damping effect can be obtained by installing one active vibration damping device M having a weight of 250 kgf. As a result, according to the vibration damping system according to the above-described embodiment, it is possible to reduce the fluctuation of the natural primary frequency in five spans by one active vibration damping device M, and thus the active required for vibration damping. The number of vibration control devices M can be further reduced to reduce costs and resources.
[0040]
In the above embodiment, only the case where the damper main body 7 is elastically supported on the base 1 by the spring 10 in the active vibration damping device M has been described. However, the present invention is not limited to this. Alternatively, another urging member having a desired elastic force such as an air damper may be used.
[0041]
【The invention's effect】
As described above, according to the vibration damping system of the first aspect, since the damper main body is vertically controlled by the linear motor drive, the frictional force is extremely small and the response is excellent. The vibration damping effect can be effectively exhibited even for a slight vibration of several μm level that could hardly be expected depending on the vibration damping device.
[0042]
Furthermore , since the controller sets the frequency weighting function for sensitivity reduction having a large weight at the specific frequency and the control gain is designed using the H-infinity control theory, the control frequency is set to the specific frequency detected by the sensor. In contrast, this can be effectively reduced, and therefore high vibration damping performance can be obtained even if the device is light and small.
[0043]
Furthermore, according to the invention described in claim 3, it is possible to simultaneously reduce input vibrations to a plurality of vibration isolating devices installed in a wide area by one active vibration damping device. Compared with this, the cost can be greatly reduced, and the level of micro vibrations such as floors can be reduced. As a result, longer spans and multiple layers can be achieved, and the degree of freedom in design is increased. Can do .
[Brief description of the drawings]
FIG. 1 is a longitudinal sectional view showing an embodiment of an active vibration damping device of the present invention.
2 is a schematic configuration diagram showing an installation state of the active vibration damping device of FIG. 1; FIG.
FIG. 3 is a diagram showing a control system in one embodiment of the vibration damping system of the present invention.
FIG. 4 is a graph showing a method of setting a weight function Ws.
FIG. 5 is a graph showing a method for setting weight functions Wt and Wn.
FIG. 6 is a graph of floor displacement showing the effect of the present invention.
7A and 7B are diagrams for explaining the effect of the active vibration damping device of FIG. 1, in which FIG. 7A is a frame size when no vibration damping device is provided, and FIG. 7B is an allowable value when an active vibration damping device is installed. The dimension of the beam, (c) is a front view showing the allowable span length when the beam is made constant.
8A and 8B show another embodiment of the present invention, in which FIG. 8A is a front view showing a state in which an active vibration damping device is installed in each span, and FIG. 8B is one active vibration damping device per layer. It is a front view which shows the state which installed.
FIG. 9 is a schematic configuration diagram showing a vibration damping system using a conventional vibration damping device.
[Explanation of symbols]
DESCRIPTION OF SYMBOLS 1 Base 2 Support | pillar 3 Linear motion ball bearing 4 Core part of damper main body 6 Excitation coil 7 Damper main body 8 Drive coil 10 Spring (biasing member)
12 Controller 15 Floor 16 Sensor

Claims (3)

A base attached to the control target, a support erected on the base, a drive coil supported on the upper end of the support, and the drive coil is inserted and moved vertically to the support via a linear motion bearing. A metal damper main body serving as a freely provided weight, an exciting coil provided in the damper main body for exciting the damper main body, and an attachment for elastically supporting the damper main body on the base or the controlled object. An active damping device comprising a biasing member and a controller for inputting a control force to the drive coil;
A sensor that is provided in the control object and detects a frequency generated in the control object;
The active vibration damping device is set to a weight corresponding to the natural frequency of the control target,
The controller sets in advance the natural frequency of the control object and the assumed specific frequency, and sets a frequency weighting function for sensitivity reduction having a large weight at the specific frequency to set an H infinite control theory. A damping system characterized in that control gain is designed using The controller is set in advance with a control gain designed using a robust stable frequency weighting function that reduces the sensitivity of the active vibration damping device at a frequency other than the natural frequency to be controlled and the specific frequency . The vibration damping system according to claim 1 . The said control object in which the said active damping device was installed is a floor comprised by the beam or slab supported by the pillar as a structural floor for installing a vibration isolator, The said 1 or 2 characterized by the above-mentioned. The vibration control system described in 1.

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