JP2000258152A - Angle gage - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an angle gage capable of being stably set to the measurement part of an object to be measured and highly accurately measuring the angle of the object to be measured. SOLUTION: This angle meter is provided with a main body part 10 provided with a first measurer member 13, a rotation part 30 provided rotatably to the main body part 10 and provided with a second measurer member 31, an angle detection part 50 for detecting the angle of the second measurer member 31 to the first measurer member 13 and an angle display part 60 for displaying the angle detected in the angle detection part 50. The first measurer member 13 is formed of two fixed blades 16 and 17 oppositely arranged with a fixed clearance and the second measurer member 31 is formed of one movable blade 32 positioned between the two fixed blades 16 and 17 and rotatably provided.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

[0001] The present invention relates to a goniometer.
More specifically, the present invention relates to a goniometer for measuring an angle of an object to be measured from an angle of a movable blade with respect to a fixed blade.

[0002]

BACKGROUND ART As a goniometer for measuring the angle of an object to be measured,
U.S. Pat. No. 5,040,298 is known.
This is a fixed arm integrally fixed to the main body of the goniometer, a movable arm rotatably provided with respect to this fixed arm, an angle sensor for detecting the rotation angle of the movable arm with respect to the fixed arm, And a digital display for digitally displaying the angle detected by the angle sensor.

[0003]

The conventional goniometer described above has a structure in which the fixed arm and the movable arm are each composed of a single plate, and the fixed arm and the movable arm rotate with the movable arm in contact with one surface of the fixed arm. In other words, since the movable arm is shifted from the fixed arm by the thickness of the fixed arm,
When these arms are brought into contact with the measurement site of the object to be measured, the goniometer tends to tilt in the thickness direction of the arms, and there is a disadvantage that stable measurement cannot be performed.

SUMMARY OF THE INVENTION An object of the present invention is to provide an angle meter which can stably set the object to be measured at a measurement site and can measure the angle of the object with high accuracy by overcoming such conventional disadvantages. is there.

[0005]

A goniometer according to the present invention has the following arrangement to achieve the above object. According to the first aspect of the present invention, a main body having a first tracing stylus member is provided rotatably with respect to the main body, and is brought into contact with a measurement site of the DUT together with the first tracing stylus member. A rotation unit having a second tracing stylus member, an angle detection unit that detects an angle of the second tracing stylus member with respect to the first tracing stylus member, and an angle that displays the angle detected by the angle detection unit. In a goniometer provided with a display unit, the first tracing stylus member is formed of two fixed blades that are arranged to face each other with a fixed gap therebetween, and the second tracing stylus member is the two tracing stylus members. And one rotatable blade rotatably provided between the fixed blades.

According to the present invention, the tracing stylus member which is in contact with the measurement site of the object to be measured is provided between the two fixed blades opposed to each other with a predetermined gap therebetween, and between the two fixed blades. , And one movable blade rotatably provided, that is, since the movable blade is located (center) between the two fixed blades,
When these blades are brought into contact with the measurement site of the object to be measured, they can be prevented from tilting in the thickness direction as much as possible. Therefore, since the blade can be stably brought into contact with the measurement site of the measurement object, the angle of the measurement region of the measurement object can be measured with high accuracy.

According to a second aspect of the present invention, in the goniometer according to the first aspect, the rotating portion includes the movable blade, a rotating plate rotatably supported by the main body, and a rotating plate. On the other hand, a holding means for holding the movable blade so that its position can be adjusted in the longitudinal direction thereof is provided. According to this invention, since the holding position of the movable member with respect to the rotating plate can be adjusted along the longitudinal direction, various shapes of the object to be measured can be adjusted by adjusting the length of the movable blade with respect to the fixed blade. Can also respond.

According to a third aspect of the present invention, in the goniometer according to the second aspect, the holding means is provided on the rotary plate, and a distance from a rotation center of the rotary plate gradually increases in one rotation direction. A handle having a decreasing cam groove, a blade base interposed between the handle and the movable blade, an engaging pin at one end for engaging the cam groove of the handle, and the other end of the movable blade And an engaging claw having an engaging portion that engages with a long groove formed along the longitudinal direction of the main body.

According to the present invention, when the handle is turned, the cam groove provided in the handle is also rotated. Then
The engaging claw that engages between the cam groove and the long groove of the movable blade approaches and separates from the rotation axis of the handle. When the engaging claw is separated from the rotation axis of the handle, the movable blade is separated from the blade base, so that the movable blade can be slid in its longitudinal direction. After the length of the movable blade is adjusted by sliding the movable blade, when the engaging claw approaches the rotation axis of the handle, the movable blade is pressed against the blade base, and the movable blade, the blade base and the handle are fixed integrally. That is, the movable blade is held at its longitudinal position. Therefore, the length of the movable blade can be adjusted with a simple configuration.

According to a fourth aspect of the present invention, in the goniometer according to any one of the first to third aspects, the angle detecting section is provided on the rotating section and has the same circle centered on a rotation axis thereof. A rotor substrate on which a plurality of electrodes are arranged at a constant angular interval, and a plurality of electrodes arranged at a constant angular interval on the same circumference centered on the rotation axis and arranged on the main body so as to face the rotor; And a capacitance type encoder provided with the stator substrate described above. According to the present invention, since the angle detection unit is configured by the capacitance type encoder including the rotor substrate and the stator substrate, it is possible to realize a small size, light weight, and low cost.

According to a fifth aspect of the present invention, in the goniometer according to the second aspect, fine movement means for finely rotating the movable blade is provided, and the fine movement means is turned around the outer periphery of the rotary plate. And a fine movement adjustment shaft which is supported by the main body so as to be slidable in the axial direction of the rotary plate and has a contact portion at its tip for pressing and contacting the elastic body.

According to the present invention, since the fine movement means for finely rotating the movable blade is provided, the movable blade can be rotated by a small angle at a time, and the movable blade can be accurately positioned on the measurement site of the object to be measured. Can be abutted. Moreover, when the fine adjustment shaft is slid and the contact portion at the tip thereof is pressed and brought into contact with the elastic body provided on the outer periphery of the rotary plate, and then the fine adjustment shaft is rotated, the elastic body that comes into frictional contact with the contact portion is rotated. Since the rotating plate is rotated through the gears, the rotation plate is rotated through gears or the like (in the case of gears, there is a possibility that backlash may occur due to backlash).
The rotating plate can be smoothly rotated. Further, when the fine movement adjusting shaft is slid and the contact portion at the tip thereof is separated from the elastic body, the resistance to the rotating plate is reduced, so that the rotating plate (movable blade) can be rotated lightly.

According to a sixth aspect of the present invention, in the goniometer according to any one of the first to fifth aspects, a rotation clamp means for clamping the rotation of the movable blade is provided. . According to the present invention, since the rotation clamp means for clamping the rotation of the movable blade is provided, the rotation of the movable blade is clamped after the movable blade and the fixed blade are brought into contact with the measurement site of the object to be measured. Since the movable blade does not rotate, it is easy to read the value on the angle display unit.

According to a seventh aspect of the present invention, in the goniometer according to any one of the first to fifth aspects, a reference value setting is provided between the two fixed blades and the movable blade is positioned. Positioning unit, memory storing preset reference angle data, first reference value setting means for setting and instructing the reference angle data stored in this memory as a reference value, and inputting arbitrary angle data Presetting means for performing the setting, second reference value setting means for setting and instructing the angle data input from the presetting means as a reference value, and the memory when the first reference value setting means is operated. Is set as a reference value of the angle detection unit, and when the second reference value setting unit is operated by the preset unit Wherein the control means for setting the force angular data as the reference value of the angle detection unit is provided.

According to the present invention, the setting of the reference value of the angle detecting section can be performed by the following two methods. In the first method, first, for example, -90 degrees is stored as reference angle data in a memory. In setting the reference value, a perpendicular reference device (square) is prepared, and the fixed blade and the movable blade are brought into contact with the reference device, and then the first reference value setting means is operated. Then, the control unit sets the reference angle data (-90 degrees) stored in the memory as a reference value of the angle detection unit. In the second method, first, the movable blade is rotated and positioned on the reference value setting positioning section provided between the two fixed blades. Subsequently, preset angle data (when the movable blade is positioned at the reference value setting unit of the two fixed blades, the angle data of the movable blade with respect to the fixed blade is previously given as designated angle data) by the preset means. input. For example, in a state where the preset mode has been entered, the rotating plate is rotated by the presetting means to set the angle detected by the angle detecting section to the designated angle. Thereafter, when the second reference value setting means is operated, the control means
The current angle data of the angle detector is set as a reference value of the angle detector. In this case, there is an advantage that the reference value can be set without using a reference device or the like. In this way,
After setting the reference value of the angle detection unit, the rotation angle data of the movable blade is counted up or down from this reference value.

[0016]

Embodiments of the present invention will be described below with reference to the drawings. FIG. 1 is a front view showing a goniometer of the present embodiment, and FIG. 2 is an exploded perspective view thereof. As shown in these drawings, the goniometer according to the present embodiment includes a first probe element 1
3 and a second tracing stylus member 31 provided rotatably with respect to the main body 10 and abutting on a measurement site of the object to be measured together with the first tracing stylus member 13. Unit 30 and an angle detecting unit 50 for detecting an angle of the second tracing stylus member 31 with respect to the first tracing stylus member 13
An angle display section 60 composed of a liquid crystal display for displaying the angle detected by the angle detection section 50; and a fine movement mechanism 70 as fine movement means for finely rotating the rotating section 30.
And a rotation clamp mechanism 80 as rotation clamping means for clamping the rotation of the rotation unit 30.

The main body 10 includes a disk-shaped base plate 11 having the first tracing stylus member 13 and an axis 1 of the base plate 11.
2 is provided with a cover 21 which is connected and fixed via a nut 20 and covers the disc-shaped portion of the base plate 11. The base plate 11 has a shaft 12 protrudingly fixed at the center thereof by a stopper member 12A, and the first tracing stylus member 13 formed at an outer peripheral edge. The first tracing stylus member 13 is formed of two fixed blades 16 and 17 which are opposed to each other with a certain gap therebetween via two connecting pins 14 and 15.
Here, the outer connecting pin 15 constitutes a reference value setting positioning section for positioning the second tracing stylus member 31 when setting the reference value of the angle detecting section 50. Further, both side edges of the two fixed blades 16 and 17 are measurement reference surfaces. On the surface of the cover 21, a rotary clamp knob 22 is screwed at the center thereof, and the angle display unit 60 is provided above the rotary clamp knob 22 and the five switches 2 are provided below the same.
4 to 28 and a fall prevention ring 29 are arranged respectively. Note that the fall prevention ring 29 is used to prevent the angle meter from falling down when the angle meter is used in an upright position (the position shown in FIG. 1), and the outer peripheral surface thereof coincides with the side surfaces of the fixed blades 16 and 17. Are arranged as follows.

The switches 24 to 28 have the following functions. ON / OFF switch 24: ON / OFF of power supply. Zero set / count-up switch 25: The display value of the angle display unit 60 is set to “zero”,
Pressing longer will change the direction of the count-up. For example, when the movable blade rotates in the clockwise direction, the count is incremented. When the switch 25 is pressed for a long time, the display value is switched so as to count up when the movable blade rotates in the counterclockwise direction. Preset switch 26: Reference angle data stored in a memory 92 described later is set as a reference value of the angle detection unit 50. Further, if the switch 26 is kept pressed, "P" is displayed and the apparatus enters the preset mode. After that, when the switch 26 is pressed, the angle data input in the preset mode is set as a reference value of the angle detection unit 50.
Here, the preset switch 26 is connected to a memory 9 described later.
A first reference value setting means for instructing to set the reference angle data stored in 2 as a reference value of the angle detection unit 50;
A preset means for inputting arbitrary angle data,
This constitutes second reference value setting means for setting and instructing the input angle data as a reference value of the angle detection unit 50. Data hold switch 27: Press once to hold the displayed value. Press again to release. Display changeover switch 28: The angle display can be switched between 60 minutes in degrees and minutes (0 ° 0 ') and decimal in decimals (0.00 °).

The rotating section 30 includes a second tracing stylus member 31, a rotating plate 35 rotatably supported on the shaft 12 of the main body 10 via a bearing 34, and a rotating plate 3.
5 includes holding means 41 for holding the second tracing stylus member 31 in a position adjustable in the longitudinal direction. The second tracing stylus member 31 is constituted by a single movable blade 32 rotatably provided between the two fixed blades 16 and 17. Both ends of the movable blade 32 are cut off diagonally (tapered surface shape), and a long groove 33 is formed along the longitudinal direction of one surface. The holding means 41 is integrally fitted to the fitting cylinder 36 of the rotating plate 35, and the distance from the rotation center of the rotating plate 35 gradually decreases in one rotation direction (clockwise direction in FIG. 2). A handle 43 having a cam groove 42,
A blade base 44 interposed between the handle 43 and the movable blade 32, an engaging pin 45 for engaging the cam groove 42 of the handle 43 at one end, and a longitudinal end of the movable blade 32 at the other end. Long groove 33 formed along the direction
And an engagement claw 47 having an engagement portion 46 that slidably engages with the engagement claw 47. Note that the outer peripheral edge of the handle 43 is formed in an uneven shape 43A.

The angle detecting section 50 includes a rotor board 51 integrally fixed to the rotating plate 35 and the cover 21.
And a stator substrate 53 fixed to the rotor substrate 51 via a main substrate 52 and opposed to the rotor substrate 51 with a predetermined gap therebetween. A plurality of electrodes (receiving electrodes) are arranged on the same circumference around the rotation axis on the rotor substrate 51 at a fixed angular interval, and the stator substrate 53 also has the same electrode on the circumference around the rotation axis. A plurality of electrodes (transmitting electrodes) are arranged on the circumference at fixed angular intervals. Since this detection principle is known, detailed description thereof will be omitted.

The fine movement mechanism 70 includes an elastic body 71 having a circular cross section swung around the outer periphery of the rotary plate 35 and the cover 2.
A fine movement adjusting shaft 72 supported so as to be slidable and rotatable in the axial direction of the rotary plate 35;
And a contact portion 74 provided on the other end of the fine movement adjustment shaft 72 and pressed against the elastic body 71. The rotary clamp mechanism 80 includes the rotary clamp knob 22 and the shaft 1
And two clamp pins 81 which are accommodated in the lower part of the two at an interval of 120 degrees so as to be able to advance and retreat in a direction orthogonal to the axis of the shaft 12 and which are in contact with the tip cone of the rotary clamp knob 22. That is, when the rotary clamp knob 22 is screwed in, the three clamp pins 81 that are in contact with the tip cone portion are rotated around the axis of the shaft 12 by three.
This is a structure that spreads in the direction and abuts against the inner peripheral surface of the fitting cylinder 36 of the rotating plate 35 to clamp it.

FIG. 3 is a block diagram of the goniometer according to the present embodiment. In the figure, reference numeral 90 denotes an arithmetic and control unit constituting a control unit. The arithmetic and control unit 90 includes a storage area 91 for storing angle data from an angle detection unit (capacitance type encoder) 50 therein, and the various switches 24 to 28, an angle display unit 60, The detection unit 50 and the memory 92 are connected to each other. Memory 9
2, reference angle data set in advance, in this case, −
90 ° angle data is stored. When the preset switch (first reference value setting means) 26 is operated, the arithmetic and control unit 90 sets the reference angle data stored in the memory 92 as the reference value of the angle detection unit 50 in the storage area 91. In addition, when the preset switch 26 (second reference value setting means) is operated in the preset data input mode, the angle data input in the preset mode is set in the storage area 91 as the reference value of the angle detection unit 50. I do. Thereby, the rotation angle data of the movable blade 32 is counted up or counted down from this reference value.

Next, a method of using the goniometer according to the present embodiment will be described. First, a reference value of the angle detection unit 50 is set. The setting of the reference value can be performed by the following two methods. In the first method, first, for example, -90 degrees is stored in the memory 92 as reference angle data.
When setting the reference value, as shown in FIG. 4, a perpendicular reference device (square) 100 is prepared, and
After bringing the movable blades 6 and 17 into contact with the movable blade 32, the preset switch 26 is operated. Then, the memory 92
Is stored in the storage area 91 as a reference value of the angle detection unit 50. Thereby, “−90 °” is displayed on the angle display unit 60.

In the second method, as shown in FIG. 5, the movable blade 32 is rotated so that the two fixed blades 16 and 1 are rotated.
7, that is, a connection pin 15
Position. Thereafter, if the preset switch 26 is kept pressed, “P” is displayed on the angle display section 60. As a result, the preset mode is entered. In this state, the movable blade 32 is removed and the handle 43 is removed.
To the designated value (when the movable blade 32 is positioned on the connecting pin 15, the angle data of the movable blade 32 with respect to the fixed blades 16 and 17 is given as designated angle data in advance) by the rotation of. Set. In this state, the preset switch 26
When is pressed, the specified value is set in the storage area 91 as a reference value of the angle detection unit 50. As a result, the designated value is displayed on the angle display unit 60. In this case, there is an advantage that the reference value of the angle detection unit 50 can be set without using a reference device or the like.

The method of use is as follows. First, the length of the movable blade 32 is set in accordance with the measurement site of the object to be measured. When the handle 43 is turned, the cam groove 42 provided in the handle 43 is also rotated. Then, this cam groove 42
The engaging claw 47 that engages with the movable blade 32 and the long groove 33 approaches and separates from the rotation axis of the handle 43 in accordance with the rotation direction of the handle. The handle 4 is moved in a direction in which the engagement claw 47 separates from the rotation axis of the handle 43.
By turning 3, the force with which the movable blade 32 is pressed against the blade base 44 is released. In this state, the length of the movable blade 32 is adjusted. After this, this time, the engaging claw 4
7 turns the handle 43 in a direction to approach the rotation axis of the handle 43. Then, the movable blade 32 is moved to the blade base 4.
4, the movable blade 32, the blade base 44
And the handle 43 are integrally fixed. That is, the movable blade 32 is held at the position in the longitudinal direction.

Next, the count-up direction is selected by the zero-set / count-up switch 25, and the angle display is set to 60 by the display switch 28.
Switch to decimal (0 ° 0 ') or decimal (0.00 °). Thereafter, the measurement is performed with the rotary clamp knob 22 loosened. The measurement was performed on fixed blades 16 and 17
Then, the movable blade 32 is brought into contact with the measurement site of the object to be measured, and the value of the angle display unit 60 at this time is read.

Therefore, according to the present embodiment, the tracing stylus member which is in contact with the measurement site of the object to be measured is made up of two fixed blades 16 and 17 which are opposed to each other with a certain gap therebetween, and Since the movable blade 32 is formed from one movable blade 32 rotatably provided between the two fixed blades 16 and 17, that is, the movable blade 32 is located between (at the center of) the two fixed blades 16 and 17. Is located, when the blades 16, 17, 32 are brought into contact with the measurement site of the measured object, the blades 16, 17, 32 can be prevented from tilting in the thickness direction as much as possible. Therefore, blade 1
6, 17, and 32 can be stably brought into contact with the measurement site of the object to be measured, so that the angle of the measurement site of the object to be measured can be measured with high accuracy.

The rotating unit 30 is provided with a movable blade 32
A rotating plate 35 rotatably supported by the base plate 11 of the main body 10, and holding means 41 for holding the movable blade 32 with respect to the rotating plate 35 in a longitudinal direction so as to be adjustable. Therefore, the holding position of the movable blade 32 with respect to the rotating plate 35 can be adjusted along its longitudinal direction. By adjusting the length of the movable blade 32 with respect to the fixed blades 16 and 17, the object to be measured can be adjusted. Various shapes can be supported.

The holding means 41 is provided with a handle 43 having a cam groove 42 which is fitted to the rotating plate 35 and whose distance from the center of rotation of the rotating plate 35 gradually decreases in one rotation direction. A blade base 44 interposed between the movable blade 32 and an engagement pin 45 at one end for engaging the cam groove 42 of the handle 43, and an engagement for engaging the long groove 33 of the movable blade 32 at the other end. When the handle 43 is turned, the cam groove 42 provided in the handle 43 is also rotated, and the engagement between the cam groove 42 and the long groove 33 of the movable blade 32 is made. Is moved toward and away from the rotation axis of the handle 43. When the engaging claw 47 is separated from the rotation axis of the handle 43, the movable blade 32 is separated from the blade base 44, so that the movable blade 32 can be slid in the longitudinal direction. After the length of the movable blade 32 is adjusted, when the engaging claw 47 is moved closer to the rotation axis of the handle 43, the movable blade 32
4, the movable blade 32, the blade base 44
And the handle 43 are integrally fixed. That is, the movable blade 32 is held at the position in the longitudinal direction. Therefore, the length of the movable blade 32 can be adjusted with a simple configuration.

The angle detecting unit 50 is provided on the rotating plate 35 of the rotating unit 30. The rotor substrate 5 has a plurality of electrodes arranged at a constant angular interval on the same circumference centered on the rotation axis.
And a stator substrate 53 disposed on the cover 21 of the main body 10 so as to face the rotor substrate 51 and having a plurality of electrodes arranged at a constant angular interval on the same circumference centered on the rotation axis. Because it was configured with a capacitive encoder,
It can be realized with small size, light weight and low cost.

Further, since a fine movement mechanism 70 for finely rotating the movable blade 32 is provided, the movable blade 3
2 can be rotated by a small angle, and the movable blade 32 can be accurately brought into contact with the measurement site of the object to be measured. In addition, the fine movement mechanism 70 has a contact between the elastic body 71 swiveled around the outer periphery of the rotating plate 35 and the cover 21 of the main body 10 so as to be slidable in the axial direction of the rotating plate 35, and the leading end thereof being pressed against the elastic body 71. Fine adjustment shaft 72 having portion 74
After the fine movement adjusting shaft 72 is slid, the contact portion 74 at the tip thereof is pressed against and brought into contact with the elastic body 71 provided on the outer periphery of the rotary plate 35, and then the fine movement adjusting shaft 7 is moved.
2 rotates, the elastic body 7 that comes into frictional contact with the contact portion 74
1, the rotating plate 35 is rotated. Therefore, as compared with a structure in which the rotating plate 35 is rotated via gears or the like (in the case of a gear, there is a risk of backlash due to backlash).
5 can be smoothly rotated. Further, when the fine movement adjusting shaft 72 is slid and the contact portion 74 at the tip thereof is separated from the elastic body 71, the resistance to the rotating plate 35 is reduced, so that the rotating plate 35 (movable blade 32) can be rotated lightly.

Further, since the rotating blade mechanism 80 for clamping the rotation of the movable blade 32 is provided, the movable blade 32 and the fixed blades 16 and 17 are brought into contact with the measurement site of the object to be measured. When the rotation is clamped, the movable blade 32 does not rotate thereafter, so that the value of the angle display unit 60 can be easily read.

In the present embodiment, the reference value of the angle detecting section 50 can be set by the following two methods.
In the first method, first, for example, -90 degrees is stored in the memory 92 as reference angle data. In setting the reference value, a perpendicular reference device (square) 100 is prepared, and the fixed blades 16 and 17 and the movable blade 32 are brought into contact with the reference device, and then the preset switch 26 is operated. Then, the reference angle data (90 degrees) stored in the memory 92 is set in the storage area 91 as a reference value of the angle detector 50. Thereby, the angle display unit 60 displays
“−90 °” is displayed. In the second method, the movable blade 32 is rotated and positioned at the reference value setting positioning section (the connection pin 15). Thereafter, the preset switch 26 is kept depressed to enter the preset mode, the handle 43 is rotated so that the display value of the angle display section 60 becomes the designated angle, and then the preset switch 26 is again turned on.
When is pressed, the specified value is set in the storage area 91 as a reference value of the angle detection unit 50. In this case, there is an advantage that the reference value can be set without using a reference device or the like.

In the above embodiment, the movable blade 3
Holding means 41 for holding position 2 in a longitudinally adjustable manner.
A handle 43 having a cam groove 42 and a blade base 4
4 and the engaging claw 47, but the present invention is not limited to this, and another configuration may be used. For example, the movable blade 32 is supported on the rotating plate 35 so as to be slidable in the longitudinal direction, and the movable blade 32 is fixed to a suitable fixing means (for example, a set screw).
May be fixed at an arbitrary position.

In the above embodiment, the angle detection unit 50
Is constituted by a capacitance type encoder, but is not limited thereto, and may be a photoelectric encoder, a magnetic encoder, or the like. Further, the fine movement mechanism 70 and the rotary clamp mechanism 80 are not limited to the structures described in the above embodiment, and may have other configurations. For example, in the fine movement mechanism 70, the rotating plate may be rotated by engagement of the carrier. Further, it is also possible to connect a transmission unit to the arithmetic and control unit 90 and transmit the measurement data to the outside through this transmission unit.

[0036]

According to the goniometer of the present invention, the fixed blade and the movable blade can be stably set on the measurement site of the object to be measured, so that the angle of the object to be measured can be measured with high accuracy.

[Brief description of the drawings]

FIG. 1 is a front view showing a goniometer according to an embodiment of the present invention.

FIG. 2 is an exploded perspective view of the embodiment.

FIG. 3 is a block diagram of the embodiment.

FIG. 4 is a diagram illustrating a first setting method for setting a reference value of an angle detection unit in the embodiment.

FIG. 5 is a diagram for explaining a second setting method for setting a reference value of the angle detection unit in the embodiment.

[Explanation of symbols]

DESCRIPTION OF SYMBOLS 10 Main body part 13 1st measuring element member 15 Connection pin (positioning part for reference value setting) 16, 17 Fixed blade 26 Preset switch (first and second reference value setting means, preset means) 30 Rotating part 31 Second Measuring element member 32 movable blade 35 rotating plate 41 holding means 42 cam groove 43 handle 44 blade base 45 engaging pin 46 engaging section 47 engaging claw 50 angle detecting section 51 rotor board 53 stator board 60 angle display section 70 fine movement mechanism (Fine movement means) 71 Elastic body 72 Fine movement adjustment shaft 73 Fine movement adjustment knob 74 Contact part 80 Rotary clamp mechanism (Rotary clamp means) 90 Arithmetic control device (Control means) 91 Storage area 92 Memory

 ──────────────────────────────────────────────────続 き Continued on the front page F term (reference) 2F062 AA72 AA73 AA74 CC22 CC26 EE01 EE05 EE07 EE63 GG38 GG41 LL09 2F063 AA31 CA21 CA34 DA02 EA03 HA01 HA08 HA11 LA10 MA04 ZA05 ZA06 2F069 AA72 GG11 GG11 DD HH15 MM38 MM40 QQ07 2F077 AA39 AA46 DD01 NN02 PP01 TT61 VV02

Claims (7)

[Claims] 1. A main body having a first probe element, and a second body rotatably provided with respect to the main body and abutting on a measurement site of an object to be measured together with the first probe element. A rotation unit having a tracing stylus member, an angle detection unit that detects an angle of the second tracing stylus member with respect to the first tracing stylus member,
In the goniometer provided with an angle display unit that displays the angle detected by the angle detection unit, the first tracing stylus member is formed of two fixed blades that are opposed to each other with a fixed gap therebetween. The angle meter, wherein the second tracing stylus member is formed of one movable blade rotatably provided between the two fixed blades. 2. The goniometer according to claim 1, wherein the rotating unit includes the movable blade, a rotating plate rotatably supported by the main body, and the movable blade with respect to the rotating plate. And a holding means for holding the position so as to be adjustable in the longitudinal direction. 3. The goniometer according to claim 2, wherein said holding means has a cam groove provided on said rotary plate, wherein a distance from a rotation center of said rotary plate gradually decreases in one rotation direction. A blade base interposed between the handle and the movable blade, and an engagement pin at one end for engaging with a cam groove of the handle, and the other end formed along the longitudinal direction of the movable blade. And an engaging claw having an engaging portion that engages with the elongated groove formed. 4. The goniometer according to claim 1, wherein the angle detecting section is provided in the rotating section and includes a plurality of electrodes on the same circumference around a rotation axis thereof. A rotor substrate arranged at a constant angular interval, and a stator substrate arranged on the main body portion so as to face the rotor and having a plurality of electrodes arranged at a constant angular interval on the same circumference around the rotation axis. An angle meter comprising a capacitance type encoder. 5. The goniometer according to claim 2, further comprising fine movement means for finely rotating the movable blade, wherein the fine movement means comprises an elastic body pivoted around an outer periphery of the rotary plate, and the main body. A fine movement adjusting shaft having a contact portion which is slidably supported in an axial direction of the rotary plate in the axial direction of the rotating plate and has a contact portion which presses and contacts the elastic body at a tip thereof. 6. The goniometer according to claim 1, further comprising a rotation clamp means for clamping the rotation of the movable blade. 7. A goniometer according to claim 1, further comprising: a reference value setting positioning section provided between said two fixed blades, wherein said movable blade is positioned. A memory storing the reference angle data stored therein, first reference value setting means for setting and instructing the reference angle data stored in the memory as a reference value, and preset means for inputting arbitrary angle data; Second reference value setting means for instructing setting of the angle data input from the preset means as a reference value, and reference angle data stored in the memory when the first reference value setting means is operated. Is set as the reference value of the angle detection unit, and the angle data input by the preset means when the second reference value setting means is operated is set in advance. And a control means for setting a reference value of the angle detection unit.