JP3799244B2 - Gas spring vibration isolator - Google Patents

Description

[0001]
[Industrial application fields]
  The present invention relates to a vibration isolator configured to support a load via a gas spring in order to install a supported body such as a semiconductor manufacturing apparatus or a precision measurement apparatus in a state of being substantially insulated from floor vibration.
[0002]
[Prior art]
  Conventionally, as a vibration isolator of this type, for example, as disclosed in Japanese Patent Application Laid-Open No. 11-132286, a diaphragm type that supports a load of a precision instrument or the like at a central portion of a casing that is substantially rectangular in a plan view. There is known an air spring provided with a bellows type air spring (hereinafter simply referred to as a bellows) so as to receive a horizontal load around the air spring. In this case, in order to improve the vibration isolation performance in the horizontal direction, the diaphragm of the central air spring is formed by a thin elastic membrane with extremely low rigidity called a rolling operation membrane, and the horizontal load is supported by a bellows provided separately. Like to do.
[0003]
  In general, in a gas spring vibration isolator, an actual vibration state of a supported body is detected by a sensor, and the vibration of the gas spring is changed by changing the gas pressure of the gas spring according to the detected value. Some have a so-called active vibration suppression function of adding a control vibration having an opposite phase (see, for example, JP-A-3-219141). A bellows as in the former conventional example is often used as a horizontal actuator for applying horizontal control vibration to a supported body.
[0004]
[Problems to be solved by the invention]
  However, if a bellows is used as a horizontal spring or actuator as in the two conventional examples, this may impair the vertical vibration isolation performance of the vibration isolation device. That is, in general, the spring characteristics in the axial direction of the bellows are very soft, but the spring characteristics in the direction orthogonal to the axis (hereinafter also referred to as the axis orthogonal direction) depend mainly on the material and shape of the rubber film. It is greatly influenced. For this reason, in order to sufficiently soften the spring characteristics in the vertical direction in the vibration isolator having the bellows arranged in the horizontal direction, the rubber film of bellows must be made to have low rigidity.
[0005]
  However, when the rigidity of the rubber film of bellows is reduced in this way, the restoring force in the direction perpendicular to the axis is reduced, so that the problem of misalignment due to hysteresis increases. On the other hand, if the rigidity of the rubber film of the bellows is increased in order to ensure the positioning accuracy, it is inevitable that the spring characteristics in the direction perpendicular to the axis become hard due to this, and accordingly, the springs in the vertical direction as a whole are isolated. The characteristic becomes hard, and this causes a reduction in vibration isolation performance.
[0006]
  The present invention has been made in view of such points, and an object of the present invention is to devise a configuration of the gas springs in a gas spring type vibration damping device including vertical and horizontal gas springs. In addition, while ensuring positioning accuracy in the vertical and horizontal directions, the characteristic of the gas spring is made as soft as possible to improve the vibration isolation performance.
[0007]
[Means for Solving the Problems]
  In order to achieve the above object, according to the solution means of the present invention, by incorporating a gimbal mechanism into a piston of a diaphragm type gas spring (hereinafter also referred to as a gimbal piston), the spring characteristic of the gas spring is not limited to the axial direction. Paying attention to the fact that the orthogonal direction can be very soft, the vertical and horizontal gas springs in the vibration isolation device are both constituted by gimbal pistons.
[0008]
  Specifically, in the first aspect of the invention, with respect to the fixed base, a vertical gas spring that supports the supported body in the vertical direction and a horizontal gas spring that supports the supported body in the horizontal direction are provided. Assuming the installed gas spring vibration isolator,The horizontal gas springs are arranged to face each other so that their central axes substantially coincide with each other at both sides in the horizontal direction across the fixed base.
[0009]
  And saidVertical and horizontalAs a gas springRespectivelyA gas chamber is formed by closing a recess provided in the fixed base so as to open outward, a piston disposed in the vicinity of the opening of the recess, and the opening periphery of the piston and the recess. It is equipped with partitioning diaphragmGetAnd a load receiving member disposed on one side relatively far from the recess in the direction of the central axis, and spaced apart from the load receiving member in the other axial direction and orthogonal to the central axis. A cylindrical piston body member elastically held by the diaphragm so as to be swingable around an arbitrary orthogonal axis, and through the center hole of the piston body member from the load receiving member While providing a support column extending toward the other side in the axial direction, the piston body member is provided with a bottomed cylindrical extending portion extending toward the other side in the axial direction so as to surround the support column, The bottom of this extensionBeforeThe tip of the support columnLet it roll freelyIt is set as the structure to pivot.
[0010]
  With the above configuration, in the gas spring type vibration isolator according to the present invention, first, the supported body is supported by the vertical gas spring, and the original characteristic of the gas spring is the axial direction, i. Since the natural frequency in the direction (resonance frequency unique to the system) is extremely low, this gas spring can provide an excellent vibration isolation effect over a wide frequency range with respect to vibration in the vertical direction.
[0011]
  Further, in the vertical gas spring, the piston body member swings around an arbitrary axis in a horizontal plane with respect to vibration in the direction perpendicular to the axis, that is, in the horizontal direction, so that the extension part of the piston body member The load receiving member pivotally supported by the bottom of the support member via the support column is displaced in the horizontal direction, thereby absorbing vibration. At this time, since the support point of the support column by the piston body member is lower than the holding position of the piston body member by the diaphragm, the spring characteristic of the diaphragm against the horizontal displacement of the load receiving member is very soft. Thus, the natural frequency can be sufficiently lowered even in the horizontal direction.
[0012]
  Furthermore, the vertical load (the axial load of the gas spring) acting on the piston body member that swings in this way via the support column prevents the piston body member from swinging, and the neutral position. Accordingly, the load receiving member positioning accuracy can be sufficiently obtained.
[0013]
  And in the said structure, since the horizontal gas spring which supports a to-be-supported body has the same structure as the above-mentioned up-and-down direction gas spring, not only the axial direction of this horizontal gas spring, Even in the vertical direction, which is one of the directions perpendicular to the axis, the spring characteristics are extremely soft, and sufficient positioning accuracy can be obtained.
[0014]
  That is, according to the vibration isolator according to the present invention, the vertical and horizontal gas springs are provided with gimbal pistons, thereby eliminating the disadvantages of bellows and the vertical direction of the vibration isolator. Excellent vibration isolation performance and high positioning accuracy in both horizontal and horizontal directionsThe
[0015]
  In addition, in the above-described configuration, the horizontal gas springs are arranged to face each other so that their central axes substantially coincide with each other at both sides in the horizontal direction across the fixed base. The member is supported at a plurality of locations separated in the horizontal direction by the pair of horizontal gas springs, and thus the load of the supported body can be stably supported.
[0016]
  According to the invention of claim 2, the lower surface of the load receiving member of the piston is supported in contact with the upper end surface of the support column, using the gas gas in the vertical direction, and the upper end surface of the support column is constituted by a spherical surface. It shall be.
[0017]
  Thus, in the vertical gas spring, not only the swing movement of the piston body member with respect to the horizontal vibration but also the load receiving member and the support column roll relatively. Since the member is displaced in the horizontal direction and the vibration is thereby absorbed, the spring characteristics in the horizontal direction of the vibration isolator are further softened. In addition, the horizontal restoring force of the vertical gas spring is reduced, but since the restoring force can be obtained by the horizontal gas spring, the vibration isolator as a wholeThenPositioning accuracy is sufficient.
[0018]
  Claim3In the invention of claimEither 1 or 2In this invention, it is assumed that there is provided a communication path that communicates the gas chambers of a pair of gas springs arranged opposite to each other in the horizontal direction.
[0019]
  As a result, the gas chambers of the pair of gas springs facing each other in the horizontal direction are communicated with each other by the communication path, so that each of the pair of gas springs has an extremely small axial spring constant. As a result, the spring constant of the vibration isolator as a whole can be minimized in the axial direction, so that the vibration isolation performance can be improved as much as possible. Even in this case, since the restoring force in the direction perpendicular to the axis is not lost in the horizontal gas spring, this makes it possible to prevent displacement.
[0020]
  Claim4In the invention of claim 1,Or 2Any ofTheIn the invention, the load receiving member is detected on the basis of the detection result of the detecting means for detecting the vertical or horizontal acceleration of the load receiving member, the adjusting means for adjusting the gas pressure of the vertical or horizontal gas spring, and the detection result of the detecting means. Control means for changing and adjusting the gas pressure of the gas spring by the adjusting means is provided so as to suppress vertical and horizontal vibrations of the member.
[0021]
  In this configuration, it is possible to actively suppress the vibration of the supported body by changing and adjusting the gas pressure of the vertical or horizontal gas spring by the operation of the adjusting means (active vibration suppression control). On the other hand, in this case, not only the vertical direction but also the horizontal gas spring is an essential component. Therefore, if a bellows or the like is used as the horizontal gas spring, the spring characteristics of the bellows in the direction perpendicular to the axis are hard. Therefore, where the reduction in vibration isolation performance cannot be avoided, claim 1 of the present application2The effect of being able to make the spring characteristics in the direction perpendicular to the axis very soft by adopting the gas spring provided with the gimbal piston also in the horizontal direction as in each of the inventions is particularly effective.
[0022]
DETAILED DESCRIPTION OF THE INVENTION
  Hereinafter, embodiments of the present invention will be described with reference to the drawings.
[0023]
  (Embodiment 1)
  FIG. 1 shows an example of a precision vibration isolation table A using a gas spring type vibration isolation device according to the present invention. This precision vibration isolation table A is, for example, a semiconductor inspection device, an electron microscope, or an optical measurement device (not shown). And other precision instruments are installed, and these instruments are installed in a state of being substantially insulated from vibrations from the floor. That is, the schematic configuration of the precision vibration isolation table A is as shown in the drawing. The lower structure portion 1 installed on the floor and the air spring type disposed at the four corners of the upper surface of the lower structure portion 1 respectively. (Isolators) and a mounting board 3 mounted on top of the four isolators 2, 2,.
[0024]
  The lower structure portion 1 is a structure in which structural members of a steel square pipe are assembled so as to have a substantially rectangular parallelepiped shape, and are adjacent to four leg portions 4, 4,. The lower beam portions 5, 5,... Extending horizontally so as to connect the two leg portions 4, 4 at the lower end side, and the upper end side outer periphery of the four leg portions 4, 4,. It is arranged so as to have a substantially rectangular frame shape, and its inner side surface is joined to the outer side surface of the leg portions 4, 4,. It is composed of upper beam portions 6, 6,. Further, horizontal plates 7, 7,... Are disposed from the upper end surfaces of the leg portions 4 to the upper surfaces of the upper beam portions 6, 6 surrounding the outer sides of the leg portions 4, and an isolator is provided on each horizontal plate 7. 2 is disposed. Further, two moving casters 8, 8,... Are disposed on the lower surfaces of the two lower beam portions 5, 5 extending in the longitudinal direction of the lower structure portion 1, and below each leg portion 4. .. Are provided on the end faces for height adjustment.
[0025]
  (Configuration of isolator)
  As shown in FIGS. 2 and 3, the isolator 2 includes an inner casing 10 (fixed base) having a substantially rectangular parallelepiped shape that is fixed to the lower structure portion 1 of the precision vibration isolation table A, and a box shape that opens downward. The outer casing 20 is formed so as to cover the inner casing 10 from above, and the outer casing 20 is provided with diaphragm air springs S1 provided on the upper portion of the inner casing 10 and on both the left and right sides, respectively. , S2 and S2. Hereinafter, in this specification, the illustrated X direction is referred to as the left-right direction, the Y direction is referred to as the front-rear direction, and the Z direction is referred to as the up-down direction.
[0026]
  In the inner casing 10, the lower end portions of the front, rear, left and right steel side wall members 10a, 10a, 10b, 10b are respectively joined to the upper surface of the same steel bottom plate member 10c, and adjacent side wall members 10a, 10b are connected to each other. These side edges are joined and integrated. Further, the left and right side wall members 10b and 10b are block-like ones having a large thickness, respectively, and concave portions 11 and 11 having a circular cross section so as to open outwardly in an intermediate portion in the vertical direction (shown only in FIG. 3). ) And a semicircular arc-shaped extending portion extending so as to face each other is formed on the upper edge portion, and a circular shape is formed between the two extending portions as shown in FIG. The opening 12 is formed.
[0027]
  The opening 12 opens to the upper surface of the inner casing 10, and a donut-shaped piston main body 13 constituting the piston of the air spring S1 is inserted therein. The piston body 13 is made of an aluminum alloy, and a center hole 13a having a circular cross section penetrates in the vertical direction along the axis Z. On the other hand, the lower half of the outer periphery has a tapered surface that is slightly reduced in diameter toward the lower end. 13b is formed. An annular diaphragm 14 is disposed so as to cover the outer peripheral taper surface 13b from the lower end surface 13c of the piston main body 13 and further extend to the outer peripheral side and close the periphery of the opening 12 from there. . That is, the upper end opening 12 of the inner casing 10 is closed by the diaphragm 14 and the piston main body 13, and the air chamber 15 is partitioned therein, and the lower end surface 13 c of the piston main body 13 faces the air chamber 15. The vertical air spring S1 that supports the load in the vertical direction is configured by receiving the air pressure.
[0028]
  The diaphragm 14 is made of a rubber elastic membrane in which a polyester fiber fabric is embedded as a reinforcing material. As shown by a virtual line in FIG. 4, the diaphragm 14 is once formed into a hat shape with a round hole in the center portion, and The peripheral wall portion is bent halfway and folded downward to form a deep dish shape indicated by a solid line in FIG. That is, the diaphragm 14 is formed with an annular roll portion 14b that is convexly curved upward and continuous with the inner peripheral end edge of the outer peripheral flange portion 14a corresponding to the flange portion of the hat, and the inner peripheral end of the roll portion 14b. An edge portion extends below the outer peripheral flange portion 14a, and an inner peripheral flange portion 14c is formed so as to surround the round hole from there toward the inner peripheral side.
[0029]
  As shown in the figure, the inner peripheral flange portion 14c of the diaphragm 14 is bonded to the lower end surface 13c of the piston main body 13 and is firmly pressed against the piston main body 13 by a washer 16 from below. On the other hand, the outer peripheral flange portion 14a of the diaphragm 14 is bonded to the upper surface of the inner casing 10, and the fastening ring 17 disposed on the upper portion thereof is fastened to the upper surface of the inner casing 10 by a bolt (not shown), It is sandwiched between the lower surface of the tightening ring 17 and the upper surface of the inner casing 10.
[0030]
  Thus, the diaphragm 14 arranged in such a manner is bent substantially uniformly over the entire circumference so that the annular roll portion 14b swells up and down between the piston body 13 and the tightening ring 17. The piston body 13 has great flexibility with respect to the displacement in the vertical direction. Further, the diaphragm 14 bends in opposite directions at the left and right roll portions 14b sandwiching the piston body 13, so that the piston body 13 can easily swing around any horizontal axis ( (See FIG. 7). On the other hand, the diaphragm 14 is extremely inflexible with respect to the displacement of the piston body 13 in the horizontal direction, so that the piston 13 hardly displaces in the horizontal direction.
[0031]
  A cylindrical piston well 18 (extending portion) is attached to the lower end surface 13c of the piston main body 13 so as to extend substantially vertically downward from the inner peripheral side thereof. The piston well 18 is made of the same aluminum alloy as the piston main body 13, and the upper end portion thereof is slightly reduced in diameter to be a reduced diameter portion 18 a that is screwed into the center hole 13 a of the piston main body 13. Then, the male screw threaded on the outer periphery of the reduced diameter portion 18a is screwed with the female thread threaded on the inner periphery of the center hole 13b, so that the upper end side of the piston well 18 together with the washer 16 is connected to the piston body 13. Are firmly concluded. The tip of the reduced diameter portion 18a of the piston well 18 protrudes into the center hole 13a of the piston body 13, and the upper end of the hollow portion 18b of the piston well 18 communicates with the center hole 13a, while the lower end of the hollow portion 18b. Is closed by a disc-shaped steel cap 19, and a well slug 19 a subjected to heat treatment to increase the surface hardness is provided on the upper surface of the cap 19 to support the lower end portion of the support rod 24 as will be described later. Is formed.
[0032]
  On the other hand, a top plate 21 (load receiving member) in contact with the mounting board 3 is disposed above the piston body 13 so as to be separated from the piston body 13. The top plate 21 is formed in a substantially rectangular plate shape, forms the ceiling portion of the outer casing 20 of the isolator 2, and the upper edges of the four side plates 22, 22,... Are coupled, and the lower edge of each side plate 22 extends to the vicinity of the upper surface of the bottom plate member 10 c of the inner casing 10.
[0033]
  An upper end portion of a support rod 24 (support column) extending in the vertical direction is fastened to a substantially central portion of the lower surface of the top plate 21, and the support rod 24 is hollow in the center hole 13 a of the piston body 13 and the piston well 18. A steel ball 25 that extends through the portion 18b and extends substantially vertically downward is in contact with the well slug 19a in a rollable manner. Further, a rubber elastic ring 26 in which a core body 26a is embedded is fitted on the lower end side of the support rod 24 so that the lower end portion of the support rod 24 is always positioned on the axis Z. In other words, the top plate 21 is pivotally supported on the bottom of the piston well 19 via the support rod 24 and is rotatable about an arbitrary axis in the horizontal direction with respect to the piston main body 13.
[0034]
  As shown in FIG. 2, when the appropriate air pressure is supplied to the air chamber 15, the lower surface of the top plate 21 is spaced apart from the upper surface of the lower fastening ring 17 and is opposed to the upper and lower sides. On the other hand, for example, when the air in the air chamber 15 is released and the air pressure is greatly reduced, the lower surface of the top plate 21 comes into contact with the upper surface of the fastening ring 17 and is supported by the inner casing 10 through the fastening ring 17. It becomes a state.
[0035]
  As described above, the isolator 2 of this embodiment is supported by the vertical air spring S1 so that the top plate 21 and the piston main body 13 are displaced integrally in the vertical direction, and the top plate 21 is supported by the top plate 21. The piston 24 is pivotally supported by the rod 24 and is supported by the diaphragm 14 so as to be swingable. The top plate 21, the support rod 24 and the piston body 13 constitute a so-called gimbal piston. Yes. First, as the characteristics of the air spring, the vibration in the vertical direction that is the axial direction has a vibration transmission characteristic as shown in FIG. 4, and the natural frequency is about 0.7 to 1.5 Hz. In addition to appearing in a very low frequency range, excellent vibration isolation performance can be obtained over a wide frequency range.
[0036]
  Further, with respect to horizontal vibration, as shown in FIG. 7, when the outer casing 20 and the support rod 24 are displaced in the horizontal direction, the piston main body 13 is held by the diaphragm 14 and an arbitrary axis in the horizontal direction. Oscillates around and this absorbs the vibrations. At this time, since the position where the lower end of the support rod 24 is pivotally supported by the well slug 19a is lower than the position where the piston body 13 is held by the diaphragm 14, the spring characteristic of the diaphragm 14 is very soft. Thus, as shown in FIG. 6 as an example, the vibration isolation performance in the horizontal direction by the isolator 2 is excellent as in the vertical direction.
[0037]
  Furthermore, the vertical load (axial load) acting on the piston body 13 that swings as shown in FIG. 7 via the support rod 24 prevents the piston body 13 from swinging and is neutral. It becomes the restoring force which tries to return to the state (state shown in FIG. 2). When the piston body 13 is returned to the neutral state by the restoring force and the support rod 24 extends in the vertical direction, the top plate 21 also returns to the predetermined origin position before the horizontal displacement. . That is, in this isolator 2, the gimbal piston of the vertical air spring S1 has a mechanical self-centering action different from that caused by the spring force of an elastic member or the like, and thus the required positioning accuracy can be obtained. Is.
[0038]
  Furthermore, in the isolator 2 of this embodiment, as an actuator for active vibration suppression control, which will be described later, the left and right side walls 10b of the inner casing 10 and the side plates 22 and 22 of the outer casing 20 facing each other are horizontally disposed. Directional air springs S2, S2 are arranged. The feature of the present invention is that each of the pair of left and right air springs S2, S2 is provided with a gimbal piston in the same manner as the vertical air spring S1.
[0039]
  That is, as shown in the drawing, both the left and right side wall members 10b, 10b in the inner casing 10 are respectively inserted into the recesses 11 opened on the outer surface thereof, and spaced apart from the side plate 22 (load receiving member) in the left-right direction. Thus, a piston body 28 having a central hole 28a similar to the vertical air spring S1 is disposed. An annular diaphragm 29 is disposed between each piston body 28 and the opening periphery of the recess 11, and an air chamber 30 is defined in the recess 11, and the piston body 28 facing the air chamber 30. When the pressure receiving surface 28b (the surface on the other side in the axial direction) receives air pressure, a left-right air spring S2 that supports a left-right load is configured.
[0040]
  An inner peripheral flange portion of a diaphragm 29 is fixed to a pressure receiving surface 28b of the piston main body 28 by a washer 31, and an outer peripheral flange portion of the diaphragm 29 is sandwiched between a side wall member 11a of the inner casing 10 and a tightening ring 32. The annular roll portion of the diaphragm 32 is located between the outer periphery of the piston 28 and the tightening ring 32. Then, by bending and deforming so that the annular roll portion undulates, the piston main body 28 is greatly displaced in the left-right direction which is the axial direction, and swings around an arbitrary axis orthogonal to the axial direction. ing. A cylindrical piston well 33 (extension portion) is attached to the piston body 28 so as to extend in the left-right direction, and the hollow portion 33a and the center hole 28a of the piston body 28 communicate with each other. A steel cap 34 is disposed on the front end side of the piston well 33 so as to close the hollow portion 33 a, and a well slug is formed on the inner surface of the cap 34, that is, on the bottom surface of the piston well 33.
[0041]
  Further, a support rod 35 (support column) is disposed extending through the hollow portion 33 a of the piston well 33 in the left-right direction coaxially with the piston well 33, and the base end portion of the support rod 35 is the side of the outer casing 20. While being fastened to the plate 22, a steel ball 36 is disposed at the tip of the support rod 35 so as to be able to turn freely against the well slug, and a rubber elastic ring 37 is extrapolated.
[0042]
  In short, in the horizontal air spring S2, the side plate 22 of the outer casing 20 is pivotally supported by the bottom of the piston well 33 via the support rod 35, and the piston main body 28 integral with the piston well 33 is provided. The side plate 22, the support rod 35, and the piston main body 28 constitute a gimbal piston. As shown in FIG. 2, in a state where an appropriate air pressure is supplied to the air chamber 30, the side plate 22 and the piston main body 28 are substantially integrally supported in the left-right direction that is the axial direction of the air spring S <b> 2. In addition to the extremely soft spring characteristics in the axial direction, the soft spring characteristics in the vertical direction and the front-rear direction, which are orthogonal to the axis, by the function of the gimbal piston as well as the air spring S1 in the vertical direction. As a result, an excellent vibration isolation performance can be obtained.
[0043]
  Further, in the horizontal air spring S2, the axial load (left-right direction in the figure) acting on the oscillating piston body 28 from the support rod 33 suppresses the oscillation of the piston body 28 and is neutral. The horizontal air spring S2 also has a mechanical self-centering action similar to the above-described vertical air spring S1, so that the required positioning accuracy can be obtained. It is
[0044]
  2 are air passages provided in the bottom plate member 10c of the inner casing 10 so as to individually communicate with the air chambers 15, 30, and 30, respectively. In addition, reference numerals 39, 39, 39 are air valves arranged to individually communicate with the air passages 38, 38,..., Respectively. Servo valves 45, 45,... (See FIG. 8) for adjusting the supply / discharge flow rate of air to the air chambers 15, 30,.
[0045]
  (Air pressure control)
  The precision vibration isolation table A according to this embodiment not only prevents transmission of vibration from the floor by the four isolators 2, 2,..., But also the air springs S1, S2 in the respective isolators 2, 2,. Is controlled by the controller 40 and the control vibration in the vertical direction and the horizontal direction is positively added to the mounting board 3 so that the vibration generated from the equipment on the mounting board 3 can be actively suppressed. It has a so-called active vibration suppression function.
[0046]
  That is, each of the isolators 2 includes, as schematically shown in FIG. 8, a non-contact displacement sensor 41 and an acceleration sensor 42 for detecting the vertical displacement and acceleration of the top plate 21, respectively, and the side plate 22 similarly. A displacement sensor 43 and an acceleration sensor 44 for detecting the horizontal displacement and acceleration of the sensor are arranged, and output signals from the sensors 41 to 44 are input to the controller 40, respectively. On the other hand, the control signal from the controller 40 is output to the servo valves 45, 45,... For each air spring S1, S2,. The air supply / exhaust flow rate to the spring air chambers 15, 30,... Is adjusted, and the pressure of each air spring is quickly changed. Although not shown, the servo valve 45 is connected to a reservoir tank that stores compressed air. Similarly, the operation of the electric pump connected to the reservoir tank maintains the air pressure in the reservoir tank at a predetermined value. It has come to be.
[0047]
  The contents of control of the servo valve 45 by the controller 40 are, for example, as shown in the block diagram of FIG. 9 for each isolator 2 for horizontal control, for example. And the duty ratio of the servo valve 45 based on the signals from the displacement sensor 43 and the acceleration sensor 44 in the horizontal direction, and outputs this as a control signal. The servo valve 45 receiving this control signal adjusts the air pressure of the horizontal air spring S2 of the isolator 2, and the vibration from the floor and the vibration generated by the equipment on the mounting board 3 become disturbance f. The outer casing 20 of the isolator 2 vibrates. At this time, the horizontal acceleration (X ″) of the top plate 21 to be controlled surrounded by the phantom line in the figure is detected by the acceleration sensor 44 and fed back to the controller 40, and 2 of the acceleration (X ″). The horizontal displacement (X-X0) of the top plate 21 corresponding to the power is detected by the displacement sensor 43 and fed back to the controller 40.
[0048]
  Then, based on the signal from the acceleration sensor 42, the horizontal vibration of the top plate 21 is canceled, that is, the horizontal vibration of the top plate 21 having the same amplitude and opposite phase as the horizontal vibration. The air pressure is calculated so that the deviation from the reference position of the top plate 21 becomes small on the basis of the signal from the displacement sensor 43. Then, the duty ratio of the servo valve 45 is calculated so that the air pressure satisfies the two conditions as much as possible.
[0049]
  Note that such air pressure control is limited by the response of the air spring and cannot follow vibrations of a very high frequency. Therefore, the active vibration suppression control corresponds to vibrations of a frequency of approximately 200 Hz or less. Will be done. For calculating the duty ratio of the servo valve 45, various conventionally known methods may be used. Although specific description is omitted here, for example, PID control can be applied. Alternatively, it is possible to apply state feedback control using information on acceleration, speed, and position in the vertical direction of the top plate 21 as state variables, and if vibrations generated by devices on the mounting board 3 are known. The feedforward control may be performed using this as a reference signal.
[0050]
  Thus, according to the above-described active vibration suppression control, the precision vibration isolation table A of this embodiment can suppress vibrations generated from equipment on the mounting board 3 and also insulate vibrations from the floor. As a result, it is possible to eliminate the resonance phenomenon of the isolator 2, and as a result, the vibration isolation performance can be further improved as shown in FIG. That is, a graph (P) indicated by a broken line in FIG. 5 is a logarithmic scale showing the transfer characteristics of horizontal vibrations of those that do not perform active vibration suppression control (hereinafter referred to as passive type), and are shown in FIG. Similar to the graph, the resonance point R1 appears in an extremely low frequency range. On the other hand, if active vibration suppression control as in this embodiment is performed, the resonance point R1 can be eliminated as shown in the graph (A) indicated by the solid line in the figure, and the frequency is lower than that of the passive type. It can be seen that even better vibration isolation performance can be obtained from the region.
[0051]
  Therefore, according to the precision vibration isolation table A according to the first embodiment, the air spring S1 having the gimbal piston is adopted as the vertical air spring S1 of each isolator 2 supporting the mounting board 3. With the spring, an excellent vibration isolation effect can be obtained over a wide frequency range in the vertical direction and the horizontal direction. In addition, a pair of air springs S2 and S2 are arranged opposite to each other so as to support a horizontal load on both the left and right sides of the isolator 2, and the air pressure of each air spring S2 is changed together with the vertical air spring S1. In addition, an active vibration damping function that actively adds control vibration that cancels the vibration to the top plate 21 is obtained, and further, the vibration isolation performance is further improved.
[0052]
  As a feature of the present invention, in the isolator 2 according to this embodiment, a bellows or the like is used by adopting the horizontal air spring S2 having a gimbal piston as in the vertical direction. In this case, there is no inconvenience such as deterioration of spring characteristics in the direction perpendicular to the axis of the air spring and lowering of the positioning accuracy, and the isolator 2 as a whole while maintaining high positioning accuracy both in the vertical direction and in the horizontal direction. A very soft spring characteristic can be obtained in all directions, and the vibration isolation performance can be improved sufficiently. In addition, this makes it possible to obtain the maximum effect of the above-described active vibration suppression control.
[0053]
  (Modification)
  FIG. 11 shows a modification in which a so-called dome gimbal piston is adopted as an air spring in the isolator 2. In addition to the gimbal piston described in the above embodiment, this dome gimbal piston is further provided with a rolling element between the top plate 21 or the side plate 22 and the support rods 24, 33 to provide air springs S1, S2. When the load in the direction perpendicular to the axis perpendicular to the axial direction is input, the top plate 21 or the side plate 22 and the rolling element relatively roll to absorb vibrations. is there.
[0054]
  Specifically, the vertical gas rod will be described. As shown in the drawing, a thick disk-shaped rolling element 48 is disposed on the upper end portion of the support rod 24 that supports the top plate 21, The upper surface of the rolling element 48 has a spherical shape, and the lower surface of the top plate 21 is in contact therewith and is supported so as to be freely rotatable. Therefore, in the vertical air spring S1, the vibration is absorbed not only by the swinging motion of the piston main body 13 but also by the rolling motion between the top plate 21 and the rolling element 48 with respect to the horizontal vibration. As a result, the spring characteristics in the horizontal direction of the isolator 2 become even softer, and the vibration isolation performance can be further improved.
[0055]
  Similarly, by using the dome gimbal piston for the pair of left and right air springs S2 and S2, the spring characteristics in the direction perpendicular to the axis, such as the vertical direction and the front-back direction, can be made even softer. Thus, the vibration isolation performance can be further enhanced.
[0056]
  As described above, for example, when a dome gimbal piston is used for the air spring S1 in the vertical direction, the horizontal spring constant decreases, so that the horizontal restoring force also decreases. Since the restoring force can be obtained by the left and right air springs S2 and S2, the positioning accuracy is sufficiently high. Further, of the four isolators 2, 2,... Of the vibration isolation table A, the two isolators 2, 2 are provided with a pair of air springs S2, S2 in the left-right direction, and the remaining two isolators 2, 2. If the pair of air springs S2 and S2 are provided in the front-rear direction for No. 2, the vibration isolation table A can obtain positioning accuracy with no excess or deficiency in the entire horizontal direction.
[0057]
  (Embodiment 2)
  12 and 13 show the configuration of an isolator 50 according to Embodiment 2 of the present invention. As is clear from FIG. 12, this isolator 50 has the same configuration as that of Embodiment 1 and its modifications. Therefore, the same members are denoted by the same reference numerals, and the description thereof is omitted.
[0058]
  The isolator 50 according to the second embodiment is a passive type that does not perform active vibration suppression control, unlike the one according to the first embodiment, and is characterized by a horizontal direction as shown in FIG. The air spring S2 is disposed not only on the left and right sides of the isolator 50 but also on the front and rear sides, and further, the air chambers 30 of the front and rear or left and right gas springs are communicated with each other.
[0059]
  Specifically, in the isolator 50 according to the second embodiment, a dome gimbal piston is first employed as the vertical air spring S1 as in the modified example. In this vertical air spring S1, since the mechanical restoring force by the gimbal mechanism can be adjusted by setting the curvature of the upper surface of the rolling element 48, the horizontal direction of the vertical air spring S1 is adjusted. The spring constant can be approximately zero.
[0060]
  12, the air chambers 30, 30,... Of the horizontal air springs S2, S2,... Are communicated with each other by a communication passage 52 communicating with the upstream side of the valves 39, 39,. Furthermore, an orifice 53 for restricting the amount of air flow is disposed in the middle of each communication passage 52. Since the air chambers 30 of the air springs S2 are communicated with each other in this manner, the air springs S2 have extremely small axial spring constants, and as described above, the air springs S1 in the vertical direction. In combination with the decrease in the horizontal spring constant at, the horizontal spring constant of the isolator 50 as a whole can be reduced as much as possible.
[0061]
  Therefore, according to the precision vibration isolation table A according to the second embodiment, the dome gimbal piston is used for the vertical air spring S1, and the air chambers 30, 30,... Of the horizontal air springs S2, S2,. Since the spring constant in the horizontal direction of the isolator 50 is reduced as much as possible by communicating with each other, and the natural frequency can be reduced to about 0 Hz. An ideal vibration isolation performance substantially free of resonance points can be obtained.
[0062]
  And even if it does so, if the pressure of the air chambers 30, 30,... In the horizontal air springs S2, S2,. In addition, by providing a tapered portion of an appropriate shape on the outer peripheral side of the piston 28, a difference occurs in the pressing force of the left and right air springs with respect to the displacement in the horizontal direction, thereby restoring in the direction perpendicular to the axis. Since a force is obtained, the isolator 50 as a whole can ensure horizontal positioning accuracy. It is to be noted that a damping force due to air flow resistance can be obtained by arranging the orifices 53, 53, ... in the communication passages 52, 52, ..., but the orifice 53 may not be provided. Is possible.
[0063]
  (Other embodiments)
  The present invention is not limited to the configurations of the first and second embodiments, and includes other various configurations. That is, the vibration isolator according to the present invention may be an active type as in the first embodiment or a passive type as in the second embodiment. What is necessary is just to provide either the gimbal piston or the dome gimbal piston as the vertical and horizontal air springs S1, S2.
[0064]
  The horizontal air spring S2 may include a pair of air springs S2 and S2 facing each other as in the first embodiment, and may be opposed to each other in the front, rear, left and right as in the second embodiment. It is possible to provide two pairs of air springs S2, S2,.Good.
[0065]
  Furthermore, instead of the air springs S1 and S2, for example, a gas spring filled with nitrogen gas or the like can be used.
[0066]
  In addition, in each of the above embodiments, the vibration isolator A is configured by using the four isolators 2 and 50. However, the present invention is not limited to this, for example, for vibration isolation support of a semiconductor manufacturing apparatus or the like. A configuration in which a mounting board designed exclusively for these devices is supported by 3 to 4 isolators (vibration isolation devices), or a movable floor embedded in a grating floor in a clean room is similarly supported by an isolator. It can also be.
[0067]
【The invention's effect】
  As described above, according to the gas spring vibration isolator according to the first aspect of the present invention, not only the vertical direction but also the gas spring that supports the supported body in the vertical and horizontal directions with respect to the fixed base is not limited. By adopting a gimbal piston in the horizontal direction, the vibration isolation performance is excellent both in the vertical direction and in the horizontal direction of the vibration isolation device without deteriorating the spring characteristics in the direction perpendicular to the axis as in the case of bellows. Both high positioning accuracy can be achieved.Moreover, the load of a to-be-supported body can be supported more stably by arrange | positioning a horizontal gas spring so that a central axis may mutually correspond substantially.
[0068]
  According to the second aspect of the present invention, the spring characteristic in the horizontal direction is obtained by adopting a configuration in which the lower surface of the load receiving member of the piston is slidably contacted and supported on the upper end surface of the support column by using a vertical gas rod. Can be further softened to further improve the vibration isolation performance.
[0069]
  Claim3According to the invention, by communicating the gas chambers of the gas springs facing each other in the horizontal direction, the spring constant in the axial direction of the pair of gas springs is minimized, and the vibration isolation performance in the horizontal direction is made as much as possible. Can be improved.
[0070]
  Claim4According to the invention, the vibration of the supported body can be actively suppressed by controlling the gas pressure of the gas spring, and the gas spring provided with the gimbal piston is employed as a horizontal actuator which is an essential component in this case. This effect is particularly effective.
[Brief description of the drawings]
FIG. 1 is a perspective view showing an overall configuration of a precision vibration isolation table A according to an embodiment of the present invention.
FIG. 2 is a perspective view showing a schematic configuration of an isolator (a gas spring vibration isolator) in a state where an outer casing is removed.
FIG. 3 is a longitudinal sectional view of an isolator.
FIG. 4 is an exploded perspective view showing a structure for attaching a piston body and a diaphragm to a casing.
FIG. 5 is a graph showing an example of vertical vibration isolation performance by an isolator.
FIG. 6 is a graph showing an example of horizontal vibration isolation performance by an isolator.
FIG. 7 corresponds to FIG. 3 in a state where the outer casing is displaced in the horizontal direction.
FIG. 8 is a schematic configuration diagram of an active vibration suppression control system of an isolator.
FIG. 9 is a block diagram of active vibration suppression control.
FIG. 10 is a graph showing the vibration isolation performance in the horizontal direction by the active vibration suppression control in comparison with the passive type.
FIG. 11 is a view corresponding to FIG. 3, showing a configuration of an isolator including a dome gimbal piston according to a modification.
12 is a view corresponding to FIG. 3, showing a configuration of a passive type isolator according to Embodiment 2. FIG.
FIG. 13 is a longitudinal sectional view showing a configuration of an isolator according to a second embodiment.
[Explanation of symbols]
  A Precision vibration isolation table
  S1,2 Air spring (Gas spring)
  Z Vertical axis
  2 Isolator (vibration isolation device)
  3 Mounting board (supported body)
  10 Inner casing (fixed base)
  11 recess
  12 opening
  13, 28 Piston body (piston body member)
  14, 29 Diaphragm
  15, 30 Air chamber (gas chamber)
  18, 33 Piston well (extension part)
  19 Well slug (bottom of extension)
  18b, 33a Hollow part
  20 Outer casing
  21 Top plate (load receiving member)
  22 Side plate (load receiving member)
  24, 35 Support rod (support column)
  40 controller (control means)
  42, 44 Acceleration sensor (detection means)
  45 Servo valve (Adjustment means)
  48 Roller
  52 communication path

Claims (4)

In a gas spring type vibration isolator provided with a vertical gas spring that supports a supported body in a vertical direction and a horizontal gas spring that supports the supported body in a horizontal direction with respect to a fixed base,
The horizontal gas springs are arranged to face each other so that the central axes substantially coincide with each other at both sides in the horizontal direction across the fixed base.
The gas springs in the vertical and horizontal directions are respectively
A recess provided to open outward in the fixed base;
A piston disposed in the vicinity of the opening of the recess;
A diaphragm that blocks the space between the piston and the opening periphery of the recess to partition the gas chamber;
The piston is
A load receiving member disposed on one side relatively far from the recess in the direction of the central axis;
A cylindrical piston body member elastically held by the diaphragm so as to be swingable around an arbitrary orthogonal axis that is spaced apart from the load receiving member in the axial direction and orthogonal to the central axis;
While a support pillar extending toward the other side in the axial direction so as to penetrate the center hole of the piston body member from the load receiving member is provided,
The piston body member is provided with a bottomed cylindrical extending portion extending toward the other side in the axial direction so as to surround the support column,
Gas spring vibration isolator which the tip end of the front Symbol support column to the bottom, characterized in that it is pivotally supported rollably abuts the extending portion. In claim 1,
The gas spring in the vertical direction is a gas spring type in which the lower surface of the load receiving member of the piston is supported in contact with the upper end surface of the support column, and the upper end surface of the support column is constituted by a spherical surface. Vibration isolator. In either claim 1 or 2,
A gas spring type vibration damping device, characterized in that a communication passage is provided for communicating the gas chambers of a pair of gas springs arranged opposite to each other in the horizontal direction . In either claim 1 or 2 ,
Detecting means for detecting acceleration in the vertical or horizontal direction of the load receiving member;
Adjusting means for adjusting the gas pressure of the vertical or horizontal gas spring;
Control means for changing and adjusting the gas pressure of the gas spring by the adjusting means is provided so as to suppress vertical and horizontal vibrations of the load receiving member based on the detection result by the detecting means. A characteristic gas spring type vibration isolator .

Images