JPH0498114A - Displacement measuring device - Google Patents

Abstract

PURPOSE:To significantly enhance displacement-measuring accuracy faithfully in response to fine contact-pressure variations during the measurement of displacement by detecting contact pressures for controlling the contact pressure against a measured object on a probe shaft in real time. CONSTITUTION:A contact pressure is detected by a contact-pressure detecting part 8, and on the basis of this detected contact pressure, the contact pressure against a measuring object on a probe shaft 3 is controlled by a contact-pressure control part 9 in real time, faithfully in response to fine contact-pressure variations during the measurement of displacement. Since it is so contrived that the contact pressure of the probe shaft 3 against the measuring object is caused by the magnetic force produced between the coils 36, 37 as well as permanent magnets 34, 35 in a contact-pressure adjusting part 7 and a core 38, the quantity of current to be passed to the coils 36, 37 can be reduced as much as the amount caused by the permanent magnets 34, 35, so that the amount of heat generation can be reduced, and a bad influence upon the measured values of displacement due to heat generation can be lessened so much. Thus, conjointly with these effects, measuring accuracy of displacement can be significantly enhanced.

Description

[Detailed Description of the Invention] [Object of the Invention] (Industrial Application Field) The present invention provides a displacement measuring device that detects the shape of an object to be measured by bringing a stylus into contact with the object and moving it relatively. Regarding.

(Prior art) A displacement measuring device that detects the shape of an object to be measured is equipped with a stylus at the tip of a probe shaft supported movably in the axial direction, and the stylus is brought into contact with the object to be measured. The stroke of the stylus, which advances and retreats following the shape of the object, is transmitted to the probe shaft. The probe shaft is supported by an air bearing in a non-contact manner to reduce frictional force. Furthermore, the stylus is adapted to contact the object to be measured with a constant contact pressure regardless of its position.

That is, FIG. 10 shows a conventional displacement measuring device (^). This displacement measuring device (^) consists of a cylindrical housing (X), an air bearing (+1) provided inside this housing (Xl), and a shaft supported by this air bearing (B) so as to be movable in the axial direction. the probe shaft (C), the stylus (f)) installed at the tip of the probe shaft (C), and the stylus (f) installed at the end of the probe shaft (C) to detect the amount of movement of the probe shaft (C). A core (F) is attached to the rear end of the probe shaft (C) with a corner cube (I), and a housing (X) is provided to surround this core (1') without contact. Bias coil (Gl
It consists of The probe shaft (C) has a rectangular cross-sectional shape, and a corresponding air bearing (B).
The bearing hole is also rectangular to prevent rotation around the axis of the probe shaft (C).

On the other hand, Fig. 11 shows another conventional displacement measuring device (the old one). (''), a probe shaft (K) that is hydrostatically supported on this bearing (J) so as to be movable in the axial direction, and this probe shaft (K).
) attached to the tip of the stylus (L), and a concave groove fM) provided along the axial direction at the rear end of the probe shaft (K).
and a rotation stopper pin (N) that protrudes so as to be loosely inserted into a groove (M) inside the housing (1). In the gap between the bearing (11) and the probe shaft (K), an air inlet (R
) is supplied with compressed air. Furthermore, the compressed air supplied to the gap between the bearing (1) and the probe shaft (K) is discharged to the outside from the air outlet [1 (Sl). Adjustment of the opening area is performed using an adjustment screw (not shown).

(Problem to be Solved by the Invention) However, in the former displacement measuring device (8), the contact pressure of the stylus (D) to the object to be measured is adjusted by adjusting the amount of current applied to the bias coil (6). This is done by adjusting the amount. Therefore, the bias coil (G)
Heat generation associated with the application of current to the device becomes a problem. That is, in precise measurements that require strict temperature control or measurements over a long period of time, the heat generated by the bias coil (G) may have a serious adverse effect on data reliability. Therefore,
In order to solve this problem, it is necessary to add a heat dissipation mechanism, but this will complicate the structure of the displacement measuring device (A).
I didn't like it by design. In addition, the conventional displacement measuring device (^) is not equipped with a sensor to detect the contact pressure of the stylus (D) on the object to be measured, so it can faithfully and immediately respond to subtle fluctuations in the contact pressure during measurement. , it was not possible to adjust the current applied to the bias coil (G).

Therefore, this problem has been a major obstacle to stable measurement of the shape of the object to be measured.

On the other hand, in the latter displacement measuring device (11), the contact pressure of the stylus (1,) to the measured object is adjusted by adjusting the opening [-1 area of the air outlet (S)] using the adjustment screw. This was done by adjusting the amount of air discharged from the air outflow D(S). For this reason, no consideration was given to changes in air bearing characteristics due to adjustment of contact pressure or fluctuations in contact pressure during measurement.

The present invention has been made in consideration of the above circumstances, and an object of the present invention is to provide a displacement measuring device that generates little heat and does not cause fluctuations in contact pressure during measurement.

[Structure 1 of the Invention (Means and Effects for Solving the Problems) The displacement measuring device of the present invention detects contact pressure in the contact pressure detection section, and based on the detected contact pressure, the contact pressure adjustment section It is designed to control the contact pressure of the probe shaft against the object to be measured, and it is possible to precisely control the contact pressure in real time by faithfully and immediately responding to subtle contact pressure fluctuations during displacement measurement.

Further, the contact pressure adjustment section hardly generates heat, and the displacement measurement value is not adversely affected by the heat generation. Therefore, these effects work together to significantly improve displacement measurement accuracy.

(Example) Hereinafter, one embodiment of the present invention will be described in detail with reference to the drawings.

FIG. 1 shows the displacement measuring device (Pl) of this embodiment. This displacement measuring device (Pl) includes a cylindrical housing (1), an air bearing (2) provided inside the housing (1), and a non-removal device that is movable in the axial direction by the air bearing (2). Contact-supported cylindrical probe shaft (3)
A stylus (4) is installed coaxially with the front end of the probe shaft (3) and directly contacts the object to be measured whose displacement is to be measured.
), a stopper (5) interposed between the probe shaft (3) and the stylus (4) and regulating the axial movement of the probe shaft (3), and a stopper (5) provided at the rear end of the probe shaft (3). A length measuring section (6) having a corner cube (6a) for detecting the amount of movement of the probe shaft (3),
), the contact pressure adjustment part (7) provided at the rear end inside the housing (1), the probe shaft (3) and the stopper (
5), which detects the contact pressure of the stylus (4) to the object to be measured, and a contact pressure adjustment unit (8) based on the detection result of the contact pressure detection unit (8). 7
) and a contact pressure control section (9) that applies a control signal to bring the contact pressure to an optimum value. Thus, the housing (1) includes a first housing part (10) that coaxially surrounds the corner cube (6a), and a first housing part (10) that is connected to the first housing part (10) and holds the contact pressure adjustment part (7). 2 housing part (11) and this second housing part (11)
A third housing part (
12), and a fourth housing part (12) that is connected to the third housing part (12) and coaxially surrounds the contact pressure detection part (8).
3), and a fifth housing part (14) which is connected to the fourth housing part (13) and into which the stopper (5) is loosely inserted coaxially.
It consists of This fifth housing part (14) is
It consists of a cylindrical part (15) and an end plate (16) provided at one end of the cylindrical part (15). A tapered surface (16a) is formed on the peripheral edge of the cylindrical portion (15) on one end side. This tapered surface (16a) has a through hole (17) whose one end opens inside the cylindrical portion (15).
The other end is open. In addition, the end plate (16) has
A through hole (18) through which a portion of the stopper (5) is inserted is coaxially bored. Further, the air bearing (2) is made of a metal bushing (1) fitted inside the third housing part (12).
9), a pair of ring-shaped guide grooves (20), (20) provided on the outer surface of this bush (19), and a bush (19) communicating with these guide grooves (20), (20).
A plurality of throttle holes (21) are drilled at equal positions in the probe shaft (3) and a pair of ring-shaped guide grooves (20L (20) in the bush (19)
It consists of exhaust holes (22), which are equally spaced between holes (21) and (22) for discharging the air supplied to the inside of the bush (19) from the throttle holes (21). Further, an exhaust hole (22a) is formed coaxially with the exhaust hole (22) at a position corresponding to the exhaust hole (22) of the third housing part (12). There is. In addition, compressed air is supplied to positions corresponding to the guide grooves (20), (20) of the third housing part (12).
Compressed air introduction hole (24) for introducing into (20), (
24) is perforated. This compressed air introduction hole (24)
, (24) are connected to a compressed air source (not shown) via a conduit (not shown). Furthermore, the stopper (5) is
It is coaxially connected to the probe shaft (3) and has a through hole (18) at one end.
) and a flange (26) provided in the middle of the shaft (25). Therefore, this flange (26) has a bush (19) and an end plate (
16) It is possible to freely advance and retreat within the range regulated by -C. Further, the stylus (11) has a base shaft (27) coaxially attached to the tip of the shaft portion (25), and a base shaft (27) that is coaxially attached to the tip of the shaft portion (25).
A ruby spherical part (28) coaxially connected to the tip of the
). On the other hand, the length measuring section (6) includes a corner cube (6a) provided with a pair of reflective surfaces (21a) and (29b) that are inclined at 45 degrees with respect to the axis of the probe shaft (3) and are perpendicular to each other. reflective surface (29a), f
Laser light (30), (31) incident and reflected at 29t+)
It consists of a laser interferometric length measuring device (32) that detects the amount of displacement of the probe axis (3) based on the interference characteristics of the probe axis (3). The laser interferometric length measuring device (32) is provided to project a laser beam (30) onto one of the pair of reflective surfaces (29aL (29b)) along the axis of the probe shaft (3). The laser beam (30) incident on one reflective surface (29a) is reflected on the other reflective surface (29b), and the reflected laser beam (31) returns to the probe axis (3). It returns to the laser interferometric length measuring device (32) along the axis of
7) includes a cylindrical bobbin (33) made of a non-magnetic material and fitted inside the second housing part (11), and this bobbin (33).
), a pair of permanent magnets (34) and (35) are buried in parallel in the axial direction, and
), (35) a pair of coils (36) wound on
(37) and the bobbin (33) of the probe shaft (3)
A cylindrical core (38B!:
It consists of And the above coil (36), (3
7) is supplied with power from a power source (not shown), and by adjusting the amount of power supplied, the coils (36), (37) and the permanent magnet (34)
, (35) and the core (38) can be changed. Since the coils (36) and (37) generate heat due to this power supply, a flange-shaped fin (
39) ... is provided protrudingly. In addition, the coil (36)
, (3'l) and permanent magnets (34), (35)
The contact pressure of the probe shaft (3) against the object to be measured is generated by the magnetic force generated between the probe shaft (3) and the core (38). In this case, permanent magnets (34), (35
) and the core (38) to obtain a fixed reference contact pressure PO. The fixed reference contact pressure PO is increased or decreased by the magnetic force generated between the coils (36), (371) and the core (38) to obtain a desired target contact pressure PA.Furthermore, As shown in FIG. 2, the contact pressure detection unit (8) is a cylindrical elastic body inserted and fixed coaxially between the shaft part (25) of the stopper (5) and the probe shaft (3). (40), and strain gauges (41) affixed at four equal locations along the circumferential direction perpendicular to the axis of the outer peripheral surface of this elastic body (39).
It consists of... These strain gauges (41)
... are provided to output a displacement detection signal SΔ... having a voltage corresponding to the amount of deformation of the elastic body (40). A plurality of through holes (42) are bored in the fourth housing part (13) surrounding the elastic body (40). Finally, the contact pressure control section (9) includes an amplifier (43) that is electrically connected to the strain gauge (41) and amplifies the displacement detection signal SA;
43) is connected to the output side of the amplified displacement detection signal SB.
... is input, and based on this displacement detection signal SB..., the amount of strain at the axial center of the elastic body (40) is calculated as the contact pressure P, and the amount of strain on the probe axis (3) of the elastic body (40) is calculated. A first calculation unit (
44), a contact pressure setting unit (45) for setting the target contact pressure PA of the probe shaft (3) with respect to the object to be measured, and a contact pressure P and inclination 8 output from the first calculation unit (44). By inputting the electrical signal SC indicating T and also inputting the electrical signal SD indicating the target contact pressure PA output from the contact pressure setting section (45), the target contact pressure PA and the contact pressure detection section (8) are input.
The contact pressure variation ΔP is the difference between the contact pressure P detected at
A control section (48) that outputs a control signal SESF to eliminate
An amplifier (49) that supplies power to (5G+) and a measurement signal SG indicating the amount of displacement of the probe axis (3) output from the laser interferometric length measuring device (32) as well as the first calculation unit (44)
Electrical signal S indicating contact pressure P and slope 8T output from
Input C to calculate the amount of strain ε at the axial center of the elastic body (40)
and a second calculation unit (51) that corrects the inclination 8T and calculates the true displacement amount of the probe axis (3).

Next, the operation of the displacement measuring device (Pl) having the above configuration will be described.

First, compressed air is supplied from a compressed air source (not shown) through the guide grooves (20), (20) through the compressed air introduction holes (2F), (24).
). Then, the compressed air flows through these guide grooves (2
G), is supplied from (20) to the gap between the probe shaft (3) and the inner wall surface of the housing (.1) via the aperture hole (21). As a result, the probe axis (3)
is hydrostatically supported in the housing (1). At this time, the compressed air ejected from the throttle hole (21)...
22)...Exhaust hole (22a)..., Through hole (17)...
・Through the through hole (42)..., it is released to the outside. Next, the stylus (4) is brought into contact with the object to be measured.

At this time, the laser beam (30) is transmitted from the laser interferometric length measuring device (32) to the corner cubes (6a) (7) and the reflecting surface (2).
9a) l: Project and receive the laser beam (31) reflected from the reflecting surface (29b) so that the amount of displacement of the probe axis (3) can be measured.

Further, a predetermined amount of power is supplied to the coils (36) and (37). Thus, the probe shaft (3) is connected to the stylus (
4) When the probe comes into contact with the object to be measured through the
3) retreats in the direction of the arrow (52a), but the coil (3)
6), (37) and permanent magnets (34), (35)
The probe shaft (3) is pushed back in the direction of the arrow (52b) by the magnetic force generated between the core (38) and the probe shaft (3), thereby generating contact pressure of the probe shaft (3) against the object to be measured. As a result, strain occurs in the elastic body (40).

As this strain occurs, the strain gauge (41)...
A displacement detection signal SA of a voltage corresponding to the amount of deformation of the elastic body (40) is transmitted from the amplifier (43)...
is output to. These amplifiers (43)... amplify the displacement detection signals SA, and output the displacement detection signals SB... to the first calculation section (44). Then, the first calculation section (44) generates the displacement detection signal SB...
Strain F in the axial center portion of the elastic body (40) based on
It is calculated as the contact pressure P, and the elastic body (40
) with respect to the axis of the probe axis (3) is calculated.

Then, from this first calculation section (44), an electric signal SC indicating the calculated contact pressure P and slope 8T is sent to a control section (48).
is output to. On the other hand, the control section (48) sets the target contact pressure PA indicated by the electrical signal SD from the contact pressure setting section (45).
and the contact pressure P detected by the contact pressure detection unit (8).
, SF are output to the amplifiers (49), (5(1).The control signals SE, SF are output to the amplifiers (491, (5(1)).
511) and the amplified control signals SE-, S
F- is supplied to the coils (36) and (37). Then, the reference contact pressure PO due to the fixed magnetic force generated between the permanent magnets (34), (35) and the core (38) is increased or decreased by the variable magnetic force generated by the power supply of the control signals SE'' and SF-. to obtain the desired target contact pressure PA. Such feedback control is continuously performed in real time during displacement measurement. On the other hand, during measurement, the second calculation unit (
51) includes a measurement signal SG indicating the amount of displacement of the probe shaft (3) from the laser interferometric length measuring device (32) and an electric signal SC indicating the contact pressure P and inclination ΔT from the first calculation section (44).
is applied. Based on the measurement signal SG and the electric signal SC, the second calculation unit (51)
The true displacement amount of the probe shaft (3) is calculated by correcting the strain amount ε and the inclination ΔT at the axial center portion of the elastic body (40).

This true amount of displacement is then displayed on a display device (not shown).

As mentioned above, the displacement measuring device (Pl) of this embodiment is
The contact pressure detection unit (8) detects the contact pressure, and based on the detected contact pressure, it faithfully and immediately responds to subtle contact pressure fluctuations during displacement measurement, and adjusts the probe axis (3) to be measured in real time. The contact pressure against objects can be controlled. In addition, the coil (36), (3'+1 and the permanent magnet (34),
(35) and the core (38) to generate contact pressure of the probe shaft (3) against the object to be measured, so the permanent magnet (34),
35), the amount of current applied to the coils (36) and (37) can be reduced, so the amount of heat generated is small, and the adverse effect of heat generation on the measured displacement value can be reduced accordingly. Therefore, these effects work together to significantly improve displacement measurement accuracy.

In addition, FIG. 3 shows a displacement measuring device according to another embodiment of the present invention (
P2) is shown. In addition, in this FIG. 3, except for the contact pressure adjustment part f7-1), the displacement measuring device ff1 (PI)
Since the configuration is the same as that, the same parts are given the same reference numerals and detailed explanations will be omitted. However, the contact pressure adjustment section (7-
1), as shown in FIGS. 4 and 5, three plate-shaped plates made of a non-magnetic material are fixedly arranged on the inner wall surface of the second housing part (11) at equal intervals in the circumferential direction. Spacer (6I)・
...and a plate-shaped laminated piezoelectric actuator (62) fixed on these spacers (61)...
, a plate-like yoke (63) made of a ferromagnetic material fixed on the piezoelectric actuator (62), and a fixed yoke (63) fixed in two stages in the axial direction on the yoke (63)... Permanent magnets (64) whose cross sections are arcuate and fixed adjacently at intervals, and these permanent magnets (64)...
Three pairs of permanent magnets (with arc-shaped cross sections) are fixed adjacent to each other at regular intervals in two stages in the axial direction, and are equally spaced on the outer peripheral surface of the probe shaft (3) so as to face the probe shaft (3). 65) It consists of... And a piezoelectric actuator (62)
... is connected to the control unit (48) via the amplifier (65)...
)It is connected to the. In addition, a piezoelectric actuator (62
) are provided to be expandable and contractible in the radial direction of the displacement measuring device (P2) by application of voltage from the amplifier (65). These piezoelectric actuators (62)...
・ is a product made by cutting and processing sintered ceramics, applying an electrode to it, and then bonding or pressing it to form a layer, and the ceramics include Pb(2+, Ti)
l]U(PZT), PbTi03 series (PT),
(Pb, La) (zr, Ti)03(r' L
Z T ) is preferred.

On the other hand, permanent magnet (64)... and permanent magnet (65)...
As shown in Figure 5, the magnetic loop (66)...
are formed, and so that an attractive force acts on each other, things that are facing each other have different polarities, and things that are arranged side by side in two adjacent stages in the axial direction have opposite polarities. It is set in. For example, if the surface of the permanent magnet (64) facing the displacement measuring device (P2) is the south pole, the surface of the permanent magnet (65) facing the permanent magnet (64) is the north pole. Further, if the surface of the permanent magnet (64) facing the displacement measuring device (P2) is the S pole, the displacement measuring device (P2) of the permanent magnet (64) provided adjacently at a constant interval in the axial direction The surface facing P2) becomes the north pole.

Then, the permanent magnet (64)... and the permanent magnet (65)
The distance between the piezoelectric actuator (62)...
It is adjusted by expanding and contracting in the direction of the arrow (67).

Therefore, in the displacement measuring device (P2) having the above configuration,
First, compressed air is introduced from a compressed air source (not shown) through the compressed air introduction hole (24), (24) and the guide groove (2G), (20
). Then, the compressed air flows through these guide grooves (2
01, (20) to the gap between the probe shaft (3) and the inner wall surface of the housing (1) via the aperture holes (21). As a result, the probe axis (3) is
It is hydrostatically supported in the housing (1). At this time, the compressed air ejected from the throttle hole (21)...
)..., exhaust hole (22a)..., through hole (17)...
・Through the through hole (42)..., it is released to the outside. Next, the stylus (4) is brought into contact with the object to be measured.

At this time, the laser beam (30) is transmitted from the laser interferometric length measuring device (32) to the reflecting surface (29a) of the corner cube (6a).
), and the displacement amount of the probe axis (3) can be measured by receiving the laser beam (31) reflected from the reflecting surface (29b). Thus, when the probe shaft (3) comes into contact with the object to be measured via the stylus (4), the probe shaft (3) retreats in the direction of the arrow (52a), but
The magnetic force generated between the permanent magnet (64) and the permanent magnet (65) causes the probe shaft (3) 4F, arrow (
52b), thereby generating contact pressure of the probe shaft (3) against the object to be measured, and as a result, strain is generated in the elastic body (40). With the generation of this strain, the elastic body (40
) Displacement detection signal SA with a voltage corresponding to the deformed eye
... is output to the amplifier (43)... In these amplifiers (43)..., the displacement detection signal S
.DELTA.... is amplified, and displacement detection signals SB... are output to the first calculation section (44). Then, the first calculation section (44)
, the elastic body (4
0) is calculated as the contact pressure P, and the inclination 8T of the elastic body (40) with respect to the axis of the probe shaft (3) is calculated. The first calculation section (44) then outputs an electric signal SC indicating the calculated contact pressure P and slope ΔT to the control section (48). on the other hand,
In the control section (48), the target contact pressure PA indicated by the electric signal SD from the contact pressure setting section (45) and the contact pressure detection section (8) are determined.
To the contact pressure variation, which is the difference between the contact pressure P detected at P
The control signal SH... for eliminating the
5) Output to... Then, the control signal SH...
is amplified by the amplifier (65), and the amplified control signal SH' is supplied to the piezoelectric actuator (62).

Then, the piezoelectric actuators (62) expand and contract in the direction of the arrow (67) according to the magnitude of the voltage of the control signal SH-. As the piezoelectric actuator (62)... expands and contracts, the permanent magnet (64)...' and the permanent magnet (65)...
The interval between the two changes. Then, as this interval changes, the magnetic attractive force between the permanent magnets (64) and the permanent magnets (65) changes inversely as shown in FIG. 6.

That is, by controlling the amount of expansion and contraction of the piezoelectric actuators (62) by applying the control signal SH-, the contact pressure of the probe shaft (3) with respect to the object to be measured can be adjusted. Here, the permanent magnet (64)... and the permanent magnet (65)...
・If you set the distance between the piezoelectric actuator (62)
It is possible to increase the change ΔM in the magnetic attraction force with respect to the displacement ΔD. Therefore, the contact pressure of the probe shaft (3) against the object to be measured can be controlled to a desired value in real time in faithful response to subtle contact pressure fluctuations during displacement measurement.

As described above, the displacement measuring device (P2) of this embodiment is
The contact pressure detection unit (8) detects the contact pressure, and based on the detected contact pressure, the contact pressure adjustment unit (7-1) faithfully and immediately responds to subtle contact pressure fluctuations during displacement measurement. , the contact pressure of the probe shaft (3) to the object to be measured can be controlled in real time.

In particular, since the piezoelectric actuator (62) constituting the contact pressure adjustment section (7-1) can strictly control the amount of expansion and contraction, it is possible to precisely control the contact pressure.

Furthermore, even if power is supplied to the piezoelectric actuators (62), there is little risk of heat generation. Therefore, these effects work together to significantly improve displacement measurement accuracy.

Next, FIG. 7 shows a displacement measuring device (P3) according to another embodiment of the present invention. In addition, in this example,
Components that are the same as those of the displacement measuring device (Pl) are denoted by the same reference numerals, and detailed description thereof will be omitted.

This displacement measuring device (P3) has a cylindrical housing (+
), an air bearing (2) provided inside the housing (+), and a cylindrical probe shaft (3) supported by the air bearing (2) so as to be movable in the axial direction in a non-contact manner.
A stylus (4) is provided coaxially with the front end of the probe shaft (3) and directly contacts the object to be measured whose displacement is to be measured, and a probe shaft is interposed between the probe shaft (3) and the stylus (4). (3) A stopper (
5), a length measuring section (6) having a corner cube (6a) provided at the rear end of the probe shaft (3) for detecting the amount of movement of the probe shaft (3), and a length measuring section (6) provided at the rear end of the probe shaft (3); and a contact pressure adjustment part (7-2) provided at the rear end inside the housing (), a probe shaft (3), and a stopper (5).
A contact pressure detection section (8) is provided between the stylus (4) and the object to be measured, and a contact pressure detection section (8) is provided between the stylus (4) and the object to be measured.
Based on the detection result in 8), the contact pressure adjustment section (7-2
) and a contact pressure control section (9) that applies a control signal to bring the contact pressure to an optimum value. Thus, the housing (1) includes a first housing part (10) that coaxially surrounds the corner cube (6a), and a part of the contact pressure adjustment part (7-21) that is connected to the first housing part (10). a second housing part (11) that holds the air bearing; a third housing part (12) that is connected to the second housing part (11) and holds the air bearing (2); and a third housing part (12) that is connected to the third housing part (12). A fourth housing part (13) coaxially surrounds the contact pressure detection part (8), and a fifth housing part (14) connected to the fourth housing part (13) into which the stopper (5) is loosely inserted coaxially. It consists of an air bearing (2
) includes a metal bushing (19) fitted into the third housing part (12), a pair of ring-shaped guide grooves (20), (20) provided on the outer surface of this bushing (19),
A plurality of throttling holes (21) are connected to these guide grooves (211) and (20) and are bored at equal locations on the bushing (19) to blow out compressed air toward the nozzle (1).
...and a pair of ring-shaped guide grooves of the bush (1g) (
20), (between 2G1 and the first housing part (10)
Adjacent to the side ring-shaped guide groove (20), υ1 air holes (υ1) are formed in an evenly open state to exhaust the air supplied to the inside of the housing (1) from the throttle holes (21) to the outside. 2
2) It consists of... Moreover, at the position corresponding to the exhaust hole (22) of the third housing part (12),
Exhaust hole (22a) coaxially with υ1 pore (22)...
)... are drilled. In addition, the third housing part (
Compressed air introduction holes (24), (24) for introducing compressed air into these guide grooves (20) (20) are bored at positions corresponding to the guide grooves (20L (20) of 12). The compressed air introduction holes (24), (24) are connected to the first compressed air source (24b) via the conduit (24a).Furthermore, the contact pressure adjustment section (7-2) teeth,
The probe shaft (3) is fitted into the second housing part (11).
a cylindrical electrostrictive element (71) into which is loosely inserted, and an electrostrictive element (71) in the third housing part (12) of the probe shaft (3).
71), and a step portion (72) provided in the vicinity of the third
Compressed air is ejected into a space (73) provided equidistantly on the inner surface of the bushing (19) fitted in the housing part (12) and sandwiched between the stepped part (72) and the electrostrictive element (71). The aperture hole (74)... and the third housing part (1
A ring-shaped guide groove (7) is provided on the outer surface of the bush (71) fitted in
5), a compressed air introduction hole (76) bored at a position corresponding to the guide groove (75) of the third housing part (I2),
A conduit (77) connected to this compressed air introduction hole (76)
and a second compressed air source (78) that supplies compressed air to the compressed air introduction hole (76) via this conduit (77). The electrostrictive element (71) is connected to the amplifier (7
9) to the control unit (48). This electrostrictive element (71) is made of fired ceramics, and the ceramics include Pb (lt, Ti)0
3 (P Z T ), 1'bTiO* system (PT), (
1′b, La)(2+4i)Og (PLZT) is preferred. Further, the electrostrictive element (71) is provided to be expandable and contractible in the radial direction of the displacement measuring device (P3) by applying a voltage from the amplifier (79). On the other hand, the probe shaft (3) has a diameter of Dl at the part where the electrostrictive element (71) is inserted, and a diameter of D2 at the part where the bushing (71) is inserted.
, the diameter D1 is smaller than the diameter D2 (Dl, <
D2) Yes.

Therefore, the stepped portion (72) is formed by the difference in diameter between the diameter D1 and the diameter D2. Furthermore, an electrostrictive element (71
) and the probe axis (3) is the gap ε1 between the bush (
71) and the probe shaft (3) (ε1<ε2) is provided smaller than the gap ε2. However, the gap ε1
is made variable by applying a voltage from the amplifier (79) to the electrostrictive element (71).

Therefore, in the displacement measuring device (P3) having the above configuration,
First, the first and second compressed air sources (2, 4b), (7
8) through the compressed air introduction holes (24), (24
), (76) to the guide groove (20), (20+, (
75). Then, the compressed air flows from these guide grooves f20), (20), and (75) to the throttle hole (21).
..., (74)... to the space (73) sandwiched between the gap ε2, the stepped portion (72), and the electrostrictive element (71). As a result, the probe axis (3
) is hydrostatically supported in the bushing (19), and at the same time,
As shown in FIG. 8, the compressed air supplied to the space (73) acts on the stepped portion (72) formed on the probe shaft (3) in the direction of the arrow (80a), and as a result, the probe Contact pressure of the shaft (3) against the object to be measured is generated.

In addition, at this time, the aperture hole (21)..., (74)
The compressed air spewed out from the exhaust hole (22)...
Exhaust hole (22a) Through hole (17)...and Through hole (42)
)... is released to the outside. At this time, the laser interferometric length measuring device (32) projects the laser beam (30) onto the reflective surface (29al) of the corner cube (6a),
The laser beam (31) reflected from the reflective surface (29b) is received so that the amount of displacement of the probe shaft (3) can be measured. Thus, the probe shaft (3) is connected to the stylus (4).
), the probe shaft (3
) retreats in the direction of the arrow (80b), but the step part (72
), the probe shaft (3) is pushed back in the direction of the arrow (BOa) by the force of compressed air acting in the direction of the arrow (80a).
) contact pressure is generated. As a result, strain occurs in the elastic body (4o).

As this strain occurs, the strain gauge (41)...
From the amplifier (43), a displacement detection signal SA of a voltage corresponding to the amount of deformation of the elastic body (40) is transmitted.
・Output to. And these amplifiers (43)...
In , the displacement detection signals SA... are amplified, and the displacement detection signals SB. are outputted to the first calculation section (44). Then, the first calculation section (44) generates the displacement detection signal SB...
Based on this, the amount of strain at the axial center of the elastic body (40) is calculated as the contact pressure P, and the inclination 8T of the elastic body (40) with respect to the axis of the probe shaft (3) is calculated.

Then, from this first calculation section (44), an electric signal SC indicating the calculated contact pressure P and slope 8T is sent to a control section (48).
is output to. On the other hand, the control section (48) sets the target contact pressure PA indicated by the electrical signal SD from the contact pressure setting section (45).
A control signal SJ for canceling the contact pressure variation ΔP, which is the difference between the contact pressure P detected by the contact pressure detection section (8)
... is output to the amplifier (79)... The control signal SJ... is amplified by the amplifier (79)..., and the amplified control signal SJ- is transmitted to the electrostrictive element (71)...
). Then, the electrostrictive element (71) expands and contracts in the direction of the arrow (81) according to the magnitude of the voltage of the control signal SJ-. As the electrostrictive element (71) expands and contracts, the gap ε between the electrostrictive element (71) and the probe shaft (3) changes. Then, as the gap ε1 changes, the force of the compressed air acting on the stepped portion (72) in the direction of the arrow (80a) also changes inversely. That is, the gap ε
1 becomes larger, the contact pressure becomes smaller, and the gap ε1
The smaller the contact pressure becomes, the larger the contact pressure becomes. Therefore, by controlling the amount of expansion and contraction of the electrostrictive element (71) by applying the control signal SJ-, the probe axis (3
) contact pressure can be adjusted. Therefore, the contact pressure of the probe shaft (3) against the object to be measured can be controlled to a desired value in real time in faithful response to subtle contact pressure fluctuations during displacement measurement.

As mentioned above, the displacement measuring device (P3) of this embodiment is
The contact pressure detection unit (8) detects the contact pressure, and based on the detected contact pressure, the contact pressure adjustment unit (7-2) faithfully and immediately responds to subtle contact pressure fluctuations during displacement measurement. , it is possible to control the contact pressure of the probe shaft (3) against the object to be measured in real time.

In particular, since the electrostrictive element (71) constituting the contact pressure adjustment section (7-2) can precisely control the amount of expansion and contraction, it is possible to precisely control the contact pressure. In addition, the electrostrictive element (71)
Even if power is supplied to the device, there is little risk of heat generation.

Therefore, these effects combine to significantly improve displacement measurement accuracy.

Next, FIG. 9 shows a displacement measuring device fW (P4) of another embodiment.
), the contact pressure adjusting section (7-3) of this displacement measuring device (P4) is connected to the first housing section instead of the electrostrictive element (71) in the displacement measuring device (P3). The flange (10g) of (10) and the third housing part (12
) A disc-shaped metal exhaust adjustment plate (91) is interposed between the flange (12g) and the flange (12g). The probe shaft (3) is loosely inserted into the exhaust adjustment plate (91) leaving a gap ε. The relationship between this gap ε and the gap ε2 between the bushing (71) and the probe shaft (3) is the same as in the case of the displacement measuring device (P3). However, the size of the gap ε1 remains unchanged. and,
In this displacement measuring device (P4), the aperture hole (74)
By adjusting the pressure of the compressed air ejected from the pipe (77) with the ejection pressure adjustment part (92) provided in the middle of the pipe (77), the arrow (80a) is adjusted with respect to the step part (72).
) changes the force of compressed air acting in the direction directly proportionally,
The contact pressure of the probe shaft (3) with respect to the object to be measured is controlled. The displacement measuring device (P4) of this embodiment also has the same effect as the displacement measuring device (P3) described above.

In addition, in the above four embodiments, the rotation of the probe axis 1
Although the first and second mechanisms are not shown, the specific system for the first rotation is not limited.

For example, by loosely inserting a pin standing upright in the radial direction on a bushing or probe shaft into a locking groove provided in the opposing probe shaft or bushing in the axial direction,
A method of rotating the probe shaft 11-th may also be used. Furthermore, in the above four embodiments, the contact pressure detection section and the contact pressure control section may be omitted, and the displacement measuring device may be provided with only the contact pressure adjustment section. Even in this case, the heat generation of the contact pressure adjustment section may be reduced. By being able to prevent this, special effects can be achieved.

[Effects of the Invention] In the displacement measuring device of the present invention, the contact pressure detection section detects the contact pressure, and based on the detected contact pressure, the contact pressure adjustment section adjusts the probe shaft to the object to be measured in real time. By controlling the contact pressure that occurs during displacement measurement, it is possible to faithfully and immediately respond to subtle contact pressure fluctuations during displacement measurement, and to precisely control the contact pressure.

In addition, the contact pressure adjustment part has almost no risk of generating heat, so
This prevents the measurement accuracy from decreasing due to heat generation.

Therefore, these effects work together to significantly improve displacement measurement accuracy.

[Brief explanation of the drawing]

FIG. 1 is a configuration diagram of a displacement measuring device according to an embodiment of the present invention, FIG. 2 is a cross-sectional view of essential parts of the displacement measuring device shown in FIG. 1, and FIG. 3 is a displacement measuring device according to another embodiment of the present invention. 4 is a sectional view of the main part of the displacement measuring device shown in FIG. 3, FIG. 5 is a sectional view taken along the line V=-■ in FIG. 4, and FIG. 7 is a configuration diagram of a displacement measuring device according to another embodiment of the present invention, FIG. 8 is an enlarged view of the main part of the displacement measuring device shown in FIG. 7, and FIG. 9 is an illustration of the operation of the measuring device. A configuration diagram of a displacement measuring device according to an embodiment of a song, and FIGS. 10 and 11 are explanatory diagrams of the prior art. (1): Housing, (2): Air bearing,
(31 nib lobe shaft, (4) stylus, (6
): Measurement section. (7): Contact pressure adjustment section, (8) Contact pressure detection section (9)
: Contact pressure control section.

Claims (10)

[Claims] (1) A cylindrical housing, a static pressure bearing provided inside the housing, a probe shaft supported by the static pressure bearing so as to be movable in the axial direction in a non-contact manner, and a probe shaft provided at one end of the probe shaft. a stylus that contacts the object to be measured; a contact pressure adjusting section that is provided on the probe shaft and a part of the housing and adjusts the magnitude of the contact pressure of the probe shaft to the object to be measured; a contact pressure detection section that is provided between the stylus and detects the contact pressure; and a contact pressure control section that applies a control signal to the contact pressure adjustment section based on the detection result of the contact pressure detection section to control the contact pressure. A displacement measuring device comprising: (2) Claim (2) characterized in that the contact pressure detection unit consists of a columnar elastic body interposed between the stylus and the probe shaft, and a strain detection sensor fixed to the outer surface of the elastic body. 1) Displacement measuring device as described. (3) A cylindrical housing, a static pressure bearing provided inside the housing, a probe shaft supported by the static pressure bearing so as to be movable in the axial direction in a non-contact manner, and a probe shaft provided at one end of the probe shaft. a stylus that is brought into contact with the object to be measured; and a contact pressure adjusting section that is provided on the probe shaft and a part of the housing and adjusts the magnitude of the contact pressure of the probe shaft against the object to be measured; The pressure adjustment part is
A magnetic attraction force is created between a cylindrical bobbin fitted inside the housing, a cylindrical core fitted externally on the probe shaft at a position opposite to the bobbin, and the core provided on the bobbin. 1. A displacement measuring device comprising: permanent magnets that are generated in a fixed manner; and a coil that is wound so as to be superimposed on these permanent magnets and that variably generates a magnetic attraction force between the permanent magnet and the core. (4) A contact pressure detection section provided on the probe shaft to detect the contact pressure of the probe shaft against the object to be measured, and a control signal sent to the coil of the contact pressure adjustment section based on the contact pressure detection result in the contact pressure detection section. Claim (3) further comprising: a contact pressure control unit that controls the contact pressure by adjusting the magnetic attraction force generated between the applied magnetic force and the core.
) Displacement measuring device described. (5) A cylindrical housing, a static pressure bearing provided inside the housing, a probe shaft supported by the static pressure bearing so as to be movable in the axial direction in a non-contact manner, and a probe shaft provided at one end of the probe shaft. a stylus that is brought into contact with the object to be measured; and a contact pressure adjusting section that is provided on the probe shaft and a part of the housing and adjusts the magnitude of the contact pressure of the probe shaft against the object to be measured; The pressure adjustment part is
A plurality of actuators are fixedly disposed on the inner wall surface of the housing at equal intervals in the circumferential direction and are displaced in the radial direction by the application of a voltage, first permanent magnets fixed on these actuators, and these first permanent magnets. second permanent magnets that are fixed to the outer circumferential surface of the probe shaft at equal intervals facing the magnets and generate a magnetic attraction force between the second permanent magnets and the first permanent magnets; A displacement measuring device characterized in that the magnetic attraction force is adjusted by changing the distance between the first permanent magnet and the second permanent magnet. (6) A contact pressure detection section provided on the probe shaft to detect the contact pressure of the probe shaft against the object to be measured, and a control signal sent to the actuator of the contact pressure adjustment section based on the contact pressure detection result in the contact pressure detection section. The displacement measuring device according to claim (5), further comprising a contact pressure control unit that controls the contact pressure by applying the contact pressure and changing the distance between the first permanent magnet and the second permanent magnet. . (7) Consisting of a cylindrical housing, a hydrostatic bearing provided inside the housing, a large diameter portion and a small diameter portion, the large diameter portion is supported by the hydrostatic bearing in a non-contact manner so as to be movable in the axial direction. a stylus provided at one end of the probe shaft and in contact with the object to be measured; and a stylus provided at one end of the probe shaft and the probe shaft provided in a part of the housing to determine the magnitude of the contact pressure of the probe shaft against the object to be measured. a cylindrical contact pressure adjusting section for adjusting the contact pressure; an electrostrictive element having a shape, a step portion formed by the small diameter portion and the large diameter portion of the probe shaft at a portion of the probe shaft near the electrostrictive element, and an electrostrictive element provided equidistantly on the housing. A displacement measuring device characterized by comprising a plurality of aperture holes that eject compressed air into the space sandwiched between the stepped portion and the electrostrictive element and apply the contact pressure to the probe shaft using the compressed air. . (8) A contact pressure detection section provided on the probe shaft to detect the contact pressure of the probe shaft against the object to be measured, and control to the electrostrictive element of the contact pressure adjustment section based on the contact pressure detection result in the contact pressure detection section. The displacement measuring device according to claim 7, further comprising a contact pressure control section that controls the contact pressure by applying a signal and changing the amount of gap between the probe shaft and the electrostrictive element. . (9) Consisting of a cylindrical housing, a hydrostatic bearing provided inside the housing, a large diameter portion and a small diameter portion, the large diameter portion is supported by the hydrostatic bearing in a non-contact manner so as to be movable in the axial direction. a stylus provided at one end of the probe shaft and in contact with the object to be measured; and a stylus provided at one end of the probe shaft and the probe shaft provided in a part of the housing to determine the magnitude of the contact pressure of the probe shaft against the object to be measured. a contact pressure adjustment part for adjustment, the contact pressure adjustment part being close to the exhaust adjustment plate attached to the housing and into which the small diameter portion of the probe shaft is loosely inserted, and the exhaust adjustment plate of the probe shaft. At the location, compressed air is ejected into a stepped portion formed by the small diameter portion and the large diameter portion of the probe shaft, and a space provided equidistantly on the housing and sandwiched by the stepped portion and the exhaust adjustment plate. and a plurality of throttle holes for applying the contact pressure to the probe shaft using the compressed air, and compressed air supply means for supplying the compressed air to these throttle holes in a pressure-adjustable manner. Displacement measuring device. (10) A contact pressure detection section provided on the probe shaft to detect the contact pressure of the probe shaft against the object to be measured, and a compressed air supply means of the contact pressure adjustment section based on the contact pressure detection result in the contact pressure detection section. Claim (9) further comprising a contact pressure control section that controls the contact pressure by applying a control signal and changing the pressure of the compressed air.
Displacement measuring device as described.