JP2008309687A - Test indicator - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a test indicator capable of excluding the effects of mechanical errors due to conventional center pinions and crown gears and achieving high accuracy. <P>SOLUTION: The test indicator is provided with a freely rockable gauge head 3; a first arm 5 connected to the gauge head 3; a second arm 6 having a sector gear 61; a pinion 71 engaged with the sector gear 61; a rotary encoder 8 for detecting the amount of rotation of the pinion 71; a display unit; and an operation display part for converting the detected amount of rotation of the pinion 71 into the amount of rocking of the gauge head 3 and displaying it on the display unit. The rotary encoder 8 includes a rotor 7 and a stator 45 coaxially provided for the pinion 71. Since the rotor 7 is arranged at a part corresponding to a conventional crown gear, it is possible to eliminate the need for conventional crown gears and center pinions, exclude the effects of errors of their engagement, and achieve high accuracy. <P>COPYRIGHT: (C)2009,JPO&INPIT

Description

  The present invention relates to a test indicator, and more specifically, a measuring element having a contact part with an object to be measured and supported so as to be swingable, a measuring element connected to a distal end part, and a sector gear provided to a base end part. The present invention relates to a test indicator having an arm.

2. Description of the Related Art Conventionally, there is known a test indicator that enlarges the swing amount of an arm connected to a measuring element based on the lever principle and displays it as a rotation amount of a pointer (see, for example, Patent Document 1). According to such a test indicator, it is possible to detect a slight swing amount of the measuring element as a large displacement amount of the pointer.
Specifically, as shown in FIG. 4, the test indicator described in Patent Document 1 includes a probe 3, a first arm 5, a second arm 6, and a pointer 23. In FIG. 4, the main body case and the cover are omitted, and only the main part is displayed.

The first arm 5 is connected to the probe 3 having a contact portion 31 with the object to be measured at the distal end portion, and the first shaft portion 51 is provided at the connection portion, and the bearing portion of the body case (not shown) is provided. Is swingably supported. Further, a main body case (not shown) includes a second arm 6 that enlarges the amount of swing of the first arm 5, a pinion 71 for transmitting the swing of the second arm 6 to the pointer 23, and the crown gear 21. And are provided.
The second arm 6 is disposed adjacent to the first arm 5 and is swingably supported by a second shaft portion 62 formed at an intermediate portion thereof. Moreover, the pinion 71 and the crown gear 21 are integrated and rotatably attached.

Further, the first arm 5 is formed with a moving surface 52 and a moving surface 53 that move according to the swing of the first arm 5 on the opposite side of the first shaft portion 51 from the measuring element 3. Has been.
The second arm 6 is in contact with each of the moving surfaces 52 and 53 formed on the first arm 5 and transmits the swing of the first arm 5 to the second arm 6. Pins 63 and 64 are provided. Further, a sector gear 61 that meshes with the pinion 71 is provided at the end of the second arm 6.

A mechanism for converting the swing amount of the probe 3 into the rotation amount of the pointer 23 in such a structure will be described below.
When the tracing stylus 3 swings in the U direction, the first arm 5 rotates counterclockwise in FIG. 4 around the first shaft portion 51. Move down. Due to the downward movement of the moving surface 53, the transmission pin 64 of the second arm 6 is also pushed downward, and accordingly, the second arm 6 rotates counterclockwise around the second shaft portion 62. To turn. At this time, the moving amount of the transmission pin 64 of the second arm 5 is larger than the swinging amount of the measuring element 3 in the U direction, and further, the moving amount of the sector gear 61 is larger than the moving amount of the transmission pin 64. Therefore, the swinging amount of the probe 3 is enlarged and converted into the moving amount of the sector gear 61.
Then, as the second arm 6 rotates counterclockwise, the pinion 71 is rotated clockwise via the sector gear 61. Further, the center pinion 22 provided integrally with the pointer 23 is rotated via the crown gear 21, and the pointer 23 is also rotated via the rotating shaft 24. In this way, the swing amount of the probe 3 is displayed as the rotation amount of the pointer 23.

On the other hand, when the tracing stylus 3 swings in the D direction, the first arm 5 rotates clockwise in FIG. 4 around the first shaft portion 51, and this time the moving surface 52 moves upward. Moving. Along with this, the transmission pin 63 of the second arm 6 is pushed upward, and the second arm 6 is counterclockwise in the same manner as the swinging of the measuring element 3 in the U direction around the second shaft portion 62. Rotate around.
In other words, the pointer 23 is always rotated in the same direction regardless of the swinging direction of the probe 3.

JP-A-6-109401

  However, in the test indicator described in Patent Document 1, mechanical errors due to the center pinion and the crown gear have an influence on the display value, and it has been difficult to eliminate the influence and achieve high accuracy.

  An object of the present invention is to provide a highly accurate test indicator by eliminating the influence of mechanical errors caused by a center pinion and a crown gear as in the prior art.

  The test indicator of the present invention has a main body case, a measuring element supported by the main body case in a swingable manner and having a contact portion with the object to be measured, a measuring element connected to the distal end, and a sector gear at the proximal end. , A pinion that meshes with the sector gear and rotates as the probe swings, a rotary encoder that detects the amount of rotation of the pinion, display means, and a pinion detected by the rotary encoder Control means for converting the amount of rotation into the amount of swing of the probe and displaying it on the display means. The rotary encoder is opposed to the rotor provided on the same axis as the pinion and the main body case through a predetermined gap. And an arranged stator.

Here, it is preferable that the rotary encoder is capable of converting the amount of rotation of the rotor into an electric signal and outputting it. And as a display means, what can digitally display the electric signal output from the rotary encoder is preferable.
According to the present invention, the swing of the probe is mechanically converted into the rotation of the pinion via the arm and the sector gear provided at the base end portion of the arm. A rotary encoder detects the rotation amount of the pinion. Then, the rotation amount of the pinion detected by the control means is converted into the swing amount of the measuring element and displayed on the display means.
In this way, because the rotor is arranged in the part corresponding to the conventional crown gear, the conventional crown gear and center pinion are unnecessary, and the meshing error of the crown gear and center pinion can be eliminated, and high accuracy is achieved. Is possible.

In the test indicator of the present invention, it is preferable that the display means includes a display case and a display substrate having a digital display unit, and the display substrate and the stator are formed as an integrated substrate.
According to the present invention, the number of components can be reduced by forming the display substrate and the stator as an integrated substrate. Further, if the stator is positioned with respect to the main body case, it is not necessary to position the display substrate separately, and the assembly work can be made more efficient. Furthermore, a transmission path for transmitting the information on the rotation amount of the rotor acquired by the stator to the display means is necessary. By forming this transmission path on the integrated substrate, the assembly of the transmission path is performed at the time of assembly. Therefore, the work such as wiring is omitted, and the assembling work is simplified.

The test indicator of the present invention preferably includes a peak hold circuit for storing the maximum value of the rotation amount of the rotor acquired by the stator, and displays the maximum value of the swing amount of the probe on the display means.
According to the present invention, the maximum value of the rotation amount of the rotor is stored in the peak hold circuit, and the maximum value of the swing amount of the probe is automatically displayed on the display means, so that the convenience in use is improved.

DESCRIPTION OF EXEMPLARY EMBODIMENTS Hereinafter, a first embodiment of the invention will be described with reference to the drawings.
FIG. 1 is a perspective view showing the appearance of the test indicator of the present embodiment. FIG. 2 is a perspective view partially showing the internal structure of the test indicator.
As shown in FIG. 1, the test indicator is a main body case 1, a cover 2, a measuring element 3 that is swingably supported by the main body case 1, and display means for digitally displaying the swinging amount of the measuring head 3. The display unit 4 is provided.

The measuring element 3 is pivotally supported by the bearing members 14 formed on the pair of bearing portions 12 and 13 of the main body case 1 while being exposed from the insertion holes 11 formed in the main body case 1.
The display unit 4 is formed in a flat disk shape, and includes a display case 41 fixed to the main body case 1 and a display substrate 42 accommodated in the display case 41. A digital display unit 43 is formed on the substrate of the display substrate 42, and the digital display unit 43 is visible from a display window 44 opened on the upper surface of the display case 41. Two switches 54 and 55 are arranged on the upper surface of the display case 41 along with the digital display unit 43. Of the two switches 54 and 55, the switch 54 functions as a power on / off switch, and the switch 55 functions as a peak hold switch described later.

Next, the internal structure of the test indicator will be described with reference to FIG.
Inside the main body case 1, there is a first arm 5 that connects the measuring element 3, and a second arm 5 that is adjacent to the first arm 5 on the opposite side of the measuring element 3 and has a sector gear 61 at the end. An arm 6, a pinion 71 that meshes with the sector gear 61, and a rotary encoder 8 that can detect the amount of rotation of the pinion 71 as an electrical signal are housed. Among these, the 1st arm 5 and the 2nd arm 6 comprise the arm of this invention. The measuring element 3, the first arm 5, and the second arm 6 have the same configuration as the conventional example and perform the same operation, and detailed description thereof will be omitted.

In this embodiment, the difference from the conventional example is that, in the conventional example, the crown gear and the center pinion integrally formed with the pinion 71 are arranged, but in this embodiment, instead of the crown gear and the center pinion. Is that a rotary encoder 8 is arranged.
The rotary encoder 8 includes a pair of rotors 7 and a stator 45, and is an ABS (absolute) type rotary encoder that detects an absolute angle within one rotation of the rotor 7.

The rotor 7 is integrated with the pinion 71 and is pivotally supported by the main body case 1. The rotor 7 is formed in a small disc shape and is configured to be rotatable via a pinion 71 by a sector gear 61 of the second arm 6.
The stator 45 is disposed at a position facing the rotor 7 with a predetermined gap from the rotor 7. The stator 45 is formed as a substrate integrated with the display substrate 42 of the display unit 4 described above. That is, the stator 45 and the display substrate 42 are formed orthogonal to each other and have a substantially T-shaped cross section as a whole. On the other hand, in the conventional test indicator, the scale plate for the pointer is arranged so as to go straight to the crown gear. Therefore, by arranging the display board 42 of the test indicator of the present embodiment so as to be orthogonal to the stator 45 (rotor 7), the conventional display case for storing the pointer is used as the display case of the present embodiment as it is. Available.

  A pattern (not shown) for detecting the rotational position of the rotor 7 is formed on each surface of the rotor 7 and the stator 45 facing each other. With these patterns, the stator 45 is rotated once per rotation of the rotor 7. A phase signal indicating a change in period is output. Since the rotor 7 rotates in accordance with the swing of the probe 3, the phase signal output from the stator 45 shows a change in one cycle due to the swing of the probe 3. In FIG. 2, the gap between the rotor 7 and the stator 45 is widened for easy viewing.

  In such a configuration, when the contact portion 31 of the measuring element 3 is brought into contact with the object to be measured and the measuring element 3 swings according to the surface shape of the measured object, the swing of the measuring element 3 is the first , Mechanically converted to rotation of the pinion 71 via the second arms 5 and 6 and the sector gear 61. Then, the rotation amount of the pinion 71 is detected by the rotary encoder 8, and the swing amount of the probe 3 is displayed on the digital display unit 43 of the display substrate 42 based on the detected electric signal.

Therefore, since the rotor 7 is arranged in a portion corresponding to the conventional crown gear, the conventional crown gear and center pinion are unnecessary, and the influence of the meshing error of the crown gear and center pinion can be eliminated, and high accuracy is achieved. Can be realized.
In addition, since the display substrate 42 and the stator 45 are formed as an integrated substrate, the number of components can be reduced. Further, if the stator is positioned with respect to the main body case, it is not necessary to position the display substrate separately, and the assembly work can be made more efficient. Furthermore, a transmission path for transmitting the electrical signal detected by the stator 45 to the display substrate 42 can be formed on the integrated substrate, and work such as wiring for the transmission path can be omitted during assembly. This makes assembly work easier.

Further, as shown in FIG. 3, the test indicator of the present embodiment includes a peak hold circuit 48 that stores the maximum value of the rotation amount of the rotor acquired by the stator.
FIG. 3 is a block diagram illustrating the configuration of the peak hold circuit 48 of the test indicator. As shown in FIG. 3, the test indicator is detected by the rotary encoder 8, the calculation control unit 47 as the control unit, the calculation control program storage unit 49, the data storage unit 50 as the storage unit, and the stator 45. A digital display unit 43 including a liquid crystal display for digitally displaying the swinging amount of the probe 3 and a peak hold switch 55 are provided. Among these, the peak control circuit 48 of the present invention is constituted by the arithmetic control program storage unit 49 and the data storage unit 50. The arithmetic control unit 47 and the peak hold circuit 48 are disposed on the display substrate 42 together with the digital display unit 43.

The arithmetic control unit 47 has a function of taking an electric signal from the rotary encoder 8 and controlling the digital display unit 43 based on various programs stored in the arithmetic control program storage unit 49. That is, the calculation control unit 47 converts the rotation amount of the pinion 71 detected by the rotary encoder 8 into the swing amount of the measuring element 3 in the digital display unit 43 when the peak hold switch 55 is not pressed. Display updated.
On the other hand, when the peak hold switch 55 is pressed, the calculation control unit 47 stores the detected rotation amount data of the pinion 71 in the data storage unit 50 and causes the digital display unit 43 to display the rotation amount data. . Then, the arithmetic control unit 47 stores the rotation amount data detected next in the data storage unit 50 and compares it with the rotation amount data stored previously. As a result, when the rotation amount data stored earlier is larger, the digital display of the digital display unit 43 is not updated. When the newly stored rotation amount data is larger, the digital display of the digital display unit 43 is updated and displayed. The display method by the arithmetic control unit 47 is repeated until the peak hold switch 55 is pressed again. The data storage unit 50 can store a plurality of detected rotation amount data in order from the latest one, in this case, 3 to 5 rotation amount data.
In such a configuration, the maximum value of the swing amount of the probe 3 can be always automatically displayed on the digital display unit 43. Therefore, convenience in use is improved.

The present invention is not limited to the above-described embodiments, and modifications, improvements, and the like within the scope that can achieve the object of the present invention are included in the present invention.
For example, in the above-described embodiment, it has been described that the arm of the present invention is configured by the first arm 5 and the second arm 6, but the present invention is not limited thereto, and the arm may be configured by a single unit. As the arm, it is sufficient that at least the probe is connected to the tip and the sector gear is provided at the base.

  INDUSTRIAL APPLICABILITY The present invention is used for a test indicator such as a lever-type dial gauge having a contact portion that is in contact with an object to be measured and is supported so as to be swingable and an arm having a contact portion connected to the tip portion it can.

The perspective view which shows the test indicator which concerns on one Embodiment of this invention. The perspective view which shows the internal structure of the said test indicator. The block diagram explaining the peak hold circuit structure of the said test indicator. The perspective view which shows the test indicator of a prior art example.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 ... Body case 3 ... Measuring element 4 ... Display unit (display means)
DESCRIPTION OF SYMBOLS 5 ... 1st arm 6 ... 2nd arm 7 ... Rotor 8 ... Rotary encoder 31 ... Contact part 41 ... Display case 42 ... Display board 43 ... Digital display part 45 ... Stator 47 ... Calculation control part (control means)
48 ... Peak hold circuit 61 ... Sector gear 71 ... Pinion.

Claims (3)

A body case,
A measuring element supported by the main body case so as to be swingable and having a contact portion with an object to be measured;
An arm having the tip connected to the distal end and a sector gear provided at the proximal end;
A pinion that meshes with the sector gear and rotates as the probe swings;
A rotary encoder that detects the amount of rotation of this pinion;
Display means;
Control means for converting the amount of rotation of the pinion detected by the rotary encoder into a swing amount of the measuring element and displaying it on the display means;
The rotary encoder includes a rotor provided coaxially with the pinion, and a stator disposed on the main body case so as to face the rotor via a predetermined gap. The test indicator of claim 1, wherein
The display means includes a display case and a display substrate having a digital display unit,
A test indicator, wherein the display substrate and the stator are formed as an integral substrate. The test indicator according to claim 1 or claim 2,
A peak hold circuit for storing a maximum value of the rotation amount of the rotor acquired by the stator;
A test indicator characterized in that a maximum value of the swinging amount of the probe is displayed on the display means.

Images