JPH0140003Y2 - - Google Patents

Description

[Detailed description of the invention] The invention consists of a ceramic score body and a slide base for a gauge that can move and stop along a groove formed on the surface of the score body. This relates to a score that can be measured extremely easily and with high precision, and that has extremely little deviation due to wear and aging.

Conventional scores can only measure the squareness of the workpiece, and the measured squareness is not expressed numerically. Moreover, when measuring the right angle, a light is shined on one side of the workpiece and the other side is checked with the naked eye to determine whether or not it is a right angle, which is extremely inaccurate.

Further, since conventional scores are made using metal materials such as iron, when used for many years, they become distorted due to wear and aging.

The present invention was proposed in view of the above.The score body is made of ceramic that has excellent wear resistance and has very little deterioration over time.The groove for guiding the slide base is placed on the surface of the score body relative to the reference surface of the score body. A magnetic absorber is provided along the length direction of the groove in a part of the bottom surface of the groove, and a permanent magnet is provided on the slide base to which gauges can be attached to which attracts the magnetic absorber.
By forming a gap between the slide base and the magnet absorber, the squareness of the workpiece can be measured numerically with extremely high precision. The aim is to provide scores with extremely few deviations.

The present invention will be explained below based on drawings of embodiments.

The score 1 of the present invention consists of a score body 2 made of ceramic and a slide base 3.

As is well known, ceramics are made from materials such as high-purity aluminum oxide, silicon oxide, and zirconium oxide, or from high-purity materials obtained by chemically reacting these materials. It is a non-magnetic material manufactured through precision control, and has excellent wear resistance, mechanical strength, and high temperature resistance.
No change over time is observed. Therefore, the score body 2
When molded with ceramic, it has excellent wear resistance,
This is an accurate score with almost no change over time.

The score main body 2 shown in FIG. 1 has a long piece 4 and a short piece 5 that are integrally formed at right angles with high precision, and a groove 6 along the length on one or both sides of the long piece 4.
has been formed. This groove portion 6 has extremely high precision and is perpendicular to a reference plane set on the lower surface of the short piece portion 5 with high precision.

A burying groove 7 narrower than the width of the groove 6 is formed along the length direction of the groove 6 on the bottom surface of the groove 6. A magnet absorber 8 made of a thinner iron plate or the like is provided in a buried manner. In order to fix the magnetic absorber 8 in the groove 7, it may be fixed from the rear surface of the long piece 4 with bolts 9 or the like, or it may be attached with an adhesive. When the magnetic absorber 8 is buried in the groove 6 in this way, the left and right parts of the bottom of the groove 6 become the sliding surfaces 10, 10 of the slide base 3, and the surface of the magnetic absorber 8 becomes the sliding surface 1.
There is a slight difference between 0 and 10.

In the embodiment of the score body 1 shown in FIG. 1, the groove portion 6 is formed only in the long piece portion 4, but as shown in FIG. Similarly, a groove 6' is formed along the length direction, a embedding groove is formed in the bottom of the groove 6', and a magnet absorber 8' is buried in the bottom of the groove 6'. The sliding surfaces 10', 10' of the slide base 3 may be formed.

The short piece part 5 has two parts on the left and right sides facing the bottom surface.
First permanent magnets 11, 11 are provided in a buried manner, and second permanent magnets 12, 12 are provided in a buried manner in the long piece portion 4 and the short side portion 5 so as to face the rear surface. The first permanent magnet 11 has a long piece 4 on the table surface.
The second permanent magnet 12 is for holding the score body 2 so that it stands upright, and the second permanent magnet 12 is for holding the score body 2 laid down on the table surface.

On the other hand, the slide base 3 has a rectangular prism shape with a short height, and has a width such that it fits closely into the groove 6. A large diameter hole 13 and a small diameter hole 14 for mounting a gauge are provided above the slide base 3 in a horizontally penetrating manner, and tapping holes 15 are formed in the front and rear. A screw hole 16 for fixing the gauge is formed so as to open at the boundary between the small diameter hole 14 and the small diameter hole 14.

The large diameter hole 13 or the small diameter hole 14 described above is equipped with a gauge a such as a dial gauge or a lever-type dial gauge.
The rod b is inserted into one of the tapping holes 15, and the operator 17, which is used as a grip when moving the slide base 3, is screwed into the screw hole 16. Screw the screw rod 18 together.

Further, a permanent magnet 19 embedded therein faces the lower surface of the slide base 3, and the slide base 3 is attracted and held in the groove portion 6 by the attractive force between the permanent magnet 19 and the magnetic absorber 8. When the slide base 3 is attracted and held in the groove 6, the lower surface of the slide base 3 comes into contact with the left and right sliding surfaces 10, 10 on the bottom of the groove 6, but there is no space between the surface of the magnetic absorber 8 and the lower surface of the slide base 3. A gap l is formed. Therefore, even if the slide base 3 is moved in the longitudinal direction of the groove portion 6 or stopped, the slide base 3 will not come into contact with the magnet absorber 8. For this reason, slide base 3
It is only necessary to process with high precision only the portions where the score main body 2 contacts, that is, the left and right side edges of the lower surface of the slide base 3, the left and right side surfaces of the groove portion 6, and the left and right sliding surfaces 10, 10 of the bottom surface. As a result, the processing steps can be significantly omitted, and the accuracy of the score 1 itself can be maintained at a high level for many years, regardless of the processing accuracy, mounting accuracy, and aging of the magnetic body 8.

The score 1 of the present invention consists of the above-described score body 2 and slide base 3, and when used, a gauge is passed through either the large diameter hole 13 or the small diameter hole 14, and the threaded rod 18 is screwed into the threaded hole 16. The slide base 3 with the gauge fixed and the operator 17 mounted in the tapping hole 15 is fitted into the groove 6 of the long piece 4, and the permanent magnet 19 is used to attract and hold the slide base 3.

4 to 6 schematically show how the score is used. In FIG. 4, the upright perpendicularity of the workpiece A is measured. That is, the workpiece A is placed upright on the table surface B, and the lower surface of the short piece 5 of the score body 2, that is, the reference surface, is placed on the table surface B, and the long piece is held upright by the first permanent magnets 11, 11. Bring part 4 close to the upright surface _A1 of workpiece A.

Then, fit the slide base 3 to which the dial gauge a is fixed into the groove 6, bring the measurement terminal at the tip of the gauge into contact with the upright surface _A1, and then slide the slide base 3
By moving along the groove 6, the upright perpendicularity of the upright surface _A1 can be measured with high accuracy, and the accuracy is expressed as a numerical value by the dial gauge a.

FIG. 5 shows the case of measuring the parallelism and distortion of a workpiece A. The score main body 2 is placed on the table surface, and the workpiece is placed while being attracted and held by the second permanent magnets 12, 12. Then, the slide base 3 to which the lever-type dial gauge a (small tester, indicator, etc.) is fixed is moved along the groove 6, and the gauge a
Run the measurement terminal C of the workpiece A onto the upper surface _A2 .
As a result, the parallelism and distortion of the workpiece A can be measured with high precision and easily as numerical values.

FIG. 6 shows grooves 6 in the long piece part 4 and the short piece part 5,
Work A using the score body 2 that formed 6'
When measuring the perpendicularity of the plane, the score main body 2 is laid down on the table surface and held by the second permanent magnets 12, 12, and the adjacent surfaces A ₃ and A ₄ of the workpiece A are separated into the long piece 4 and the short piece. parallel to 5. Then, by moving the slide base 3 with the dial gauge a attached along the long piece groove 6 and the short piece groove 6', the plane perpendicularity of the surfaces A ₃ and A ₄ of the workpiece A can be determined with high precision.
Moreover, it can be measured numerically. In this case, the slide base to which the dial gauge is attached may be moved to the long groove portion 6 and the short groove portion 6' individually, or may be moved simultaneously.

The score body 2 is not limited to the L-shape described above, but may have any shape as long as it has a flat reference surface and the groove portion 6 can be formed at right angles to the reference surface. good. For example, the score main body 2 shown in the embodiment of FIG. 7 has an upper surface serving as a reference surface,
It is a ceramic cylinder having a lower surface and a circumferential surface perpendicular to the upper and lower surfaces, and a groove 6 is formed on the circumferential surface at right angles to the upper and lower surfaces.
A magnet absorber 8 is embedded in the bottom surface of the base in the same manner as in the above embodiment,
First permanent magnets 11, 11 are embedded in the lower surface. Note that when the slide base 3 is fitted into the groove 6, the surface of the magnet absorber 8 and the sliding surfaces 10, 10 of the groove 6 are arranged so that a gap is formed between the lower surface of the slide base 3 and the magnet absorber 8. Let a step be formed.

The gap l between the lower surface of the slide base 3 and the surface of the magnetic absorber 8 is not limited to the case where a step is formed between the surface of the magnetic absorber 8 and the bottom surface of the groove portion 6. For example, the 8th
As shown in the figure, a magnetic absorber 8 is fixed in a protruding manner approximately at the center of the bottom of the groove 6, an relief groove 20 is formed on the lower surface of the slide base 3, and the slide base 3 is fixed to the bottom of the groove 6.
When fitted, a gap l may be formed between the surface of the magnetic body 8 and the inner surface of the relief groove 20 on the lower surface of the slide base 3. By providing the escape groove 20 on the lower surface of the slide base 3 in this way, the gap l
By forming the groove 6, it is only necessary to machine the groove 6 in a simple shape in ceramic, which is relatively difficult to machine. Therefore, even if the score body 2 is made of ceramic, the molding, finishing steps, etc. can be carried out rationally. Note that the slide base 3 does not need to be made of ceramic; for example, if it is made of iron, even if it has a complicated shape, it can be easily machined with high precision.

Alternatively, the bottom surface of the groove portion 6 and the surface of the magnetic body 8 may be made the same plane, and the portion of the lower surface of the slide base 3 facing the magnetic absorber 8 may be formed into a concave shape. Note that the gap l in this proposal is preferably 0.05 mm or more.

As explained above, according to the present invention, a groove for guiding the slide base is formed on the surface of the ceramic score body at right angles to the reference plane of the score body, and a magnetic absorption material is formed on a part of the bottom surface of the groove. are provided along the length of the groove, and the slide base to which gauges can be attached is provided with a permanent magnet that attracts the magnet absorber, and a gap is formed between the lower surface of the slide base and the surface of the magnet absorber. The squareness of a workpiece can be measured with extremely high precision.

In addition, because the score body is made of ceramic and the slide base and magnetic absorber do not come into contact with each other, there is almost no deviation due to wear or aging even after many years of use. Accuracy can be maintained for many years.

Furthermore, since it is only necessary to process the slide base so that there is a gap between the lower surface of the slide base and the magnet absorber, precision processing can be performed rationally in score production even when using ceramic, which is difficult to process compared to iron etc. be able to.

[Brief explanation of the drawing]

The drawings show an embodiment of the present invention; FIG. 1 is an exploded perspective view, FIG. 2 is a plan view showing a section of a part of the score body in which grooves are formed in the long and short pieces, and FIG. 3 is a longitudinal sectional view of the assembled state, FIGS. 4 to 6 are schematic diagrams of the measurement state, FIG. 7 is a perspective view of another embodiment of the score body, and FIG. 8 is a slide base with a concave lower surface. FIG. 7 is a cross-sectional view of another embodiment. 1...Score, 2...Score body, 3...Slide base, 6...Groove portion, 8...Magnetic absorber, 19...
...Permanent magnet, l...gap.

Claims (1)

[Scope of utility model registration request] Consisting of a ceramic score body and a slide base to which gauges can be attached, a groove for guiding the slide base is formed on the surface of the score body at right angles to the reference plane of the score body, and the bottom surface of the groove is formed at right angles to the reference plane of the score body. A magnetic absorber is provided in a part of the groove along the length direction of the groove, and a permanent magnet that attracts the magnetic absorber faces the lower surface of the slide base, and when the slide base is fitted in the groove, the slide base and A score formed by forming a gap between the lower surface of the slide base and the surface of the magnetic material to prevent contact with the magnetic absorbing material.