JPH0212566Y2 - - Google Patents

Description

[Detailed Description of the Invention] [Industrial Field of Application] This invention relates to an inner diameter measuring device, and particularly relates to an improvement of a digital display type inner diameter measuring device.

[Prior art]

2. Description of the Related Art Conventionally, devices for measuring the inner diameter of an object to be measured include a contact type inner diameter measuring device, an optical type inner diameter measuring device, and a contact type universal measuring device.

Universal measuring instruments and optical internal diameter measuring instruments use an optical reading method, so there are visual errors due to posture and individual errors due to the habits of the measurer. Requires proficiency to remove terms. Also, the metal scale for reading the amount of movement is 1/10000mm.
Guarantees are not possible with existing technology and an act of correction is required.

When measuring the inner diameter using a contact-type universal measuring device, accurate and precise measurements are made by finding the point with zero horizontal inclination, and subtracting the known diameter of the contact ball from the amount of movement of the specimen. It takes an extremely long time to do so. In addition, since it is a universal measuring instrument, there is no consideration for X-axis and Y-axis measurements, and it is necessary to fix the ring gauge during measurement.

On the other hand, in the case of a contact type internal diameter measuring device, the axis of the measured value display section is perpendicular to the diameter to be measured. In order to change the measuring direction only on the right angle axis, it is necessary to use intermediate levers, ramps or other mechanisms, and relatively large measuring forces are required to overcome bearing and guide friction.

Therefore, the only human operation required is to read the minimum value from the vertical and vertical movements along the orthogonal axis, but this may cause elastic deformation and plasticity due to the above principle. Further, no consideration is given to the vertical movement of the measuring table, making it difficult to measure the top, middle, and bottom of the object to be measured. Therefore, errors occur due to mismatching of measurement points.

[Purpose of invention]

This idea was made in view of the above-mentioned conventional problems, and it is a digital display type inner diameter measuring device that can easily and reliably perform precise and accurate measurements for all calibration and ring gauge measurement items. It is intended to provide. That is, a measuring stand that is always kept parallel to the measuring terminal portion, a moving terminal that is displaced by contacting the ring gauge, a linear scale that detects the amount of displacement of the moving terminal, and a digital display device that displays the amount of displacement. In this digital display type inner diameter measuring instrument, by raising and lowering the measuring stand while keeping it parallel to both measurement terminals at all times, it is possible to easily measure the top, middle, and bottom of the inner diameter surface 1 of the object to be measured, making it easy to compare. The maximum value, that is, the measured value, can be obtained by sliding the ring gauge with a manual screw without requiring a large measuring force.

Another object of the present invention is to provide a measuring instrument that facilitates calibration using a block gauge by providing a reference plane on the sides of both measuring terminals.

[Structure of the idea]

The present invention will be described in detail below with reference to the drawings.

In the drawings, 1 is the base of this device, 2 is the base 1
3 is a moving block that can freely move back and forth in the direction of arrow A along a guide rail 4 that is integrated with the base 1; 5 is a moving screw that passes through the measuring block 2; The threaded portion 5a is inserted into the moving block 3 and screwed into the moving block 3.
Therefore, when the screw 5 is rotated, the moving block 3 moves in the direction of arrow A on the screw portion 5a. Reference numeral 6 denotes a measuring table which can be moved up and down in the direction of arrow B with respect to the moving block 3 together with a shaft 7 inserted into the moving block 3. Reference numeral 8 is inserted into the moving block 3 to drive the measuring table 6 up and down via a cam mechanism (not shown). 9 is a guide pin that is integrated with the measuring table 6 and whose lower end is inserted into the moving block 3 to prevent rotation of the measuring table 6; 10 is a guide pin that is passed through a support plate 11 that is integrated with the moving block 3 and is attached to a compression spring. 12 is a push rod that is always biased in the direction of arrow C, 13 is a support member that is positioned and fixed to the moving block 3, and a support pin 13 that is biased in the projecting direction is attached at the tip.
a is provided and is interposed in the notch 6a of the measuring table 6. 14 is a knob for positioning the support member 13 in the vertical direction with respect to the measuring table 6; 15 is a manual screw screwed into the support plate 16 which is positioned and fixed to the moving block 3; and this screw 15 is rotated. Therefore, the tip 15a of the measuring table 6
It is positioned so that it can move forward and backward with respect to the notch 6b. A fixed shaft 17 is inserted into the measuring block 2, positioned and fixed, and a fixed terminal 18 is integrally formed at the tip. 19
20 is a fixing screw for fixing the fixed shaft 17 after positioning it so that it can move forward and backward, 20 is a moving shaft that is slidably inserted into the fixed shaft 17, and the notch 6c of the measuring table 6
A movable terminal 21 is integrally formed at the distal end thereof. A linear scale 22 is inserted into the measurement block 2 from the side facing the fixed shaft 17, and the tip of its detection shaft 22a is connected to the end surface of the moving shaft 20 by a magnet, although not shown. Therefore, the moving shaft 20 is always urged in the direction of arrow D together with the detection shaft 22a. 23 is a display device for digitally displaying the detection signal from the linear scale 22 via the cable 24.

[Effect]

Next, a case will be described in which the apparatus according to the present invention having such a configuration is operated.

First, the display device 23 is calibrated, and the gauge used therein is constructed as shown in FIG. 3a. That is, plate-shaped block gauges 25, 27
, a reference block gauge 26 disposed between the block gauges 25 and 27, a box-shaped gauge holder 28 that accommodates these block gauges 25, 26, and 27, and an elongated hole 28a and a spacer provided in the gauge holder 28. 29 and gauge holder 28
A movable spacer 31 provided at one end of a screw 30 screwed into the block gauge 27.
is positioned by a spacer 29, and the block gauge 25 is positioned and fixed in the gauge holder 28 together with the block gauges 26 and 27 via a movable spacer 31 by turning a screw 30. The gauge thus assembled is placed on the measuring stand 6 as shown in FIG. . At this time, the block gauge 27 is connected to the fixed terminal 18.
If the inner surfaces of the terminals 18,
21 detects the length of the reference gauge block 26. Therefore, if the display device 23 is preset here, the detection signal from the linear scale 22 will correspond to the reference value and the calibration will be completed.

Next, the case of measuring the inner diameter of a ring gauge W as shown in FIG. 4a will be described. The ring gauge W is placed on the measuring table 6 so as to accommodate both terminals 18 and 21 as shown in FIG.
By pressing against the urging force in the direction of arrow D, the movable terminal 21 can be easily housed in the ring gauge W.

Next, the inner diameter of the ring gauge W is measured, and a support pin 13a is positioned on the outer peripheral surface of the ring gauge W by being moved up and down via the knob 14 as appropriate. Therefore, the ring gauge W is always urged to rotate toward the manual screw 15 by the urging force in the protruding direction of the pin 13a. The manual screw 15 is also vertically positioned by a long hole in a support plate 16 (not shown). Here, if the manual screw 15 is turned to rotate the ring gauge W in both directions while supporting it by the biasing force of the support pin 13a, the maximum value displayed on the display device 23 allows the gauge W to be easily adjusted.
The inner diameter of can be measured.

The above operating procedure is performed for each of the thickness direction positions h ₁ , h ₂ , and h ₃ of the ring gauge W. In that case, use the lifting knob 8 to move the measuring table 6 up and down in the direction of arrow B to adjust the position as appropriate. Just set it to the position.

In this way, the inner diameter of the ring gauge W is measured at each height position h ₁ , h ₂ , h _{3 ,} and the inspection as a gauge used for checking disc-shaped parts is completed.

When measuring ring gauges W of different sizes, the measuring table 6 is moved together with the moving block 3 via the moving screw 5 in the direction of the arrow A, and the distance between the measuring block 2 and the measuring table 6 is adjusted so as not to interfere. It is also possible to set it to a certain degree. At this time, fixed axis 1
By loosening the fixing screws 19 accordingly, the measuring table 7 can be expanded and contracted as appropriate to maintain its relative position with the measuring table 6.

[Effect of idea]

As described above, the present invention has the following effects.

(1) By providing a device for moving the measurement table up and down, it is possible to easily and reliably measure the top, middle, and bottom of the object to be measured.

(2) The reference plane of movable and fixed terminals facilitates the arrangement of block gauges and eliminates individual differences.

(3) Since the block gauge can be placed in the gauge holder closer to the value of the object to be measured, comparative measurements can be made, allowing for more precise measurements.

(4) Since the measuring table and both movable and fixed terminals are kept parallel, it is possible to eliminate individual differences in operation, where the maximum value is determined by simply sliding the object to be measured using a fine movement device.

(5) By connecting the moving terminal and linear scale,
By providing a separate digital display device, visual errors caused by humans can be completely eliminated and reading can be facilitated.

[Brief explanation of the drawing]

The drawings show an embodiment of the present invention; FIG. 1 is a plan view, FIG. 2 is a side view, FIGS. 3 a and b are explanatory diagrams showing the reference block gauge and the calibration state, and
Figures a and b are explanatory diagrams showing a ring gauge and its measurement state. 1... Base, 3... Moving block, 4... Guide rail, 5... Moving screw, 6... Measuring stand, 8...
... Lifting knob, 10 ... Push rod, 13 ... Support member, 13a ... Support pin, 15 ... Manual screw, 1
8... Fixed terminal, 21... Moving terminal, 22... Linear scale, 23... Display device.

Claims (1)

[Claims for Utility Model Registration] (1) A measuring stand for placing an object to be measured attached to a moving block movable in the plane X-axis direction, and an object to be measured placed on the measuring stand. a fixed terminal that abuts and is fixed to a first inner diameter portion of the terminal; a movable terminal that abuts a second inner diameter portion opposite to the first inner diameter portion and moves in the X axis; An inner diameter measuring device comprising: a linear scale that outputs a measurement signal according to the amount of movement of a moving terminal; and a display device that displays a measured value based on the output of the linear scale; a support pin that biases the outer circumference of the object to be measured on the measuring table in the plane Y-axis direction from the outer circumference; A manual screw is provided on the outer periphery of the object to be measured and is movable back and forth, and by moving the manual screw forward and backward as appropriate, the object to be measured is swung in the Y-axis direction on the measuring table, and the display device is rotated. An inner diameter measuring device characterized in that it is configured to measure the inner diameter of the object to be measured by reading the maximum value. (2) Registration of a utility model characterized in that the fixed terminal and the movable terminal have measuring end surfaces at coincident positions parallel to the moving direction of the movable terminal and perpendicular to the measuring table. An inner diameter measuring device according to claim (1).