KR19980079104A - Vernier Caliper - Google Patents

Abstract

The present invention relates to a vernier caliper, the subchuck 20 is inserted into the main chuck 10 so as to be slidable, and the mother inner jaws 11 and the mother jaws 12 provided above and below the main chuck 10. The vernier inner jaw 21 and the vernier jaw 22, which have a curved shape, are provided to correspond to the mother inner jaw 11 and the mother jaw 12 above and below the subchuck 20, and have a curved shape. In addition, the dimensions can be measured by the opening width between the tip ends 11a, 21a; 12a, 22a of the two jaws 11, 21; 12, 22 corresponding to each other, thereby forming a step or a deep groove. The thickness and groove width of the object to be measured can be measured simply and precisely.

Description

Vernier calipers

The present invention relates to a vernier caliper for measuring the size of the parts and objects of the machine, the respective jaws provided in the main and secondary chuck formed in a curved shape and then the two corresponding jaws It is related with the vernier caliper which used the tip of a jaw, and was able to measure the dimension of the to-be-measured object in which a step | channel or deep groove was formed.

In general, the vernier caliper is a measuring device for precisely measuring the thickness, depth, etc. of an article in a machine shop, etc., as shown in FIG. 3, the main chuck 103 having a mother inner jaw 101 and a mother jaw 102 above and below. The chuck 104 is slidably inserted into the chuck 104, and the chuck 104 has a vernier inner jaw 105 and a vernier jaw 106 corresponding to the mother inner jaw 101 and the mother jaw 102. The subchuck 104 is slid relative to the main chuck 103 to measure the dimensions of the object 107.

However, in the conventional vernier caliper made as described above, the section 101a, 102a, 105a, 106a of each jaw (101, 102, 105, 106) in contact with the object to be measured 107 has a straight shape, so that its cross-sectional shape is short. If deep grooves are formed and both ends are difficult to access jaws 101, 102, 105, 106 of the caliper, the jaws 101, 102, 105, 106 approach the jaws 101, 102, 105, 106.

For example, as shown in Fig. 4, in the case of the members 108 and 109 having the industrial cross section or the deep groove, and the cross section is continuous without being exposed to the outside, the pillar portion of the industrial shaped member 108 When measuring the thickness t of the 108a or the groove width d of the member 109 on which the deep groove 109a is formed, the wing portion at the time of measuring the pillar thickness t unless the respective members 108 and 109 are cut. When the groove width d is measured under the interference of the 108b, the dimension cannot be measured by the interference of the protrusion 109b.

Of course, the column thickness t of the industrial member 108 is indirectly obtained by subtracting the length from the two ends of the wing portion 108b to the column portion of the total length of the wing portion 108b. Although it can be, but there is a problem that it is difficult to obtain a precise measurement value due to the accumulation of errors generated when measuring the various parts.

Accordingly, an object of the present invention is to provide a vernier caliper, which is designed to solve the above problems, and to measure a dimension precisely by easily approaching a jaw, even when a workpiece having a step or a deep groove is formed. .

The present invention for achieving the above object is inserted into the main chuck having the mother inner jaw and the mother jaw above and below so that the chuck of the vernier inner jaw and vernier jaw can slide to measure the size of the measured object. Each jaw has a curved shape, and the groove width is measured by measuring the opening width of the tip when the ends of the mother inner jaw and the vernier inner jaw are in contact with the inner surface of the groove. It is possible to measure the thickness of the object under measurement by measuring the opening width of the tip when the tip of the near jaw comes into contact with the object under measurement.

Therefore, the vernier caliper of the present invention made as described above has a structure in which each jaw is bent, thereby allowing the jaw to approach the jaw to avoid the interference of the wing portion or the protruding jaw so that the measured object can be easily measured.

1 is a side view of a vernier caliper according to the present invention,

2a and 2b is a state of use of the vernier caliper of the present invention,

3 is a side view of a conventional vernier caliper,

4A and 4B are schematic perspective views of an object to be measured.

Explanation of symbols on the main parts of the drawings

10: main ship 11: mother inside

12: mother Joo 20: chuck

21: Vernier inner jaw 22: Vernier jaw

11a, 12a, 21a, 22a: Jaw tip 30, 40: member to be measured

31: pillar portion 32: wing portion

41a, 41b: home

Hereinafter, with reference to the accompanying drawings, the present invention will be described in detail.

Figure 1 is a side view of the vernier caliper according to the present invention, Figure 2a and Figure 2b is a state diagram of the use of the vernier caliper of the present invention, the present invention is inserted into the main chuck 10 so that the chuck 20 is slidably inserted. The main chuck 10 has upper and lower mother inner jaws 11 and mother jaws 12, and the subchuck 20 has upper and lower vernier inner jaws 12 corresponding to the upper and lower mother jaws 12. 21) and vernier jaw 22 are provided.

Here, the mother inner jaw 11 and the vernier inner jaw 21 corresponding thereto have a curved shape, so that the tip ends 11a and 21a of the two jaws 11 and 21 are formed in the hole wall surface or the groove wall surface of the object to be measured. The inner diameter and the groove width can be measured by contacting the.

The mother jaws 12 and the corresponding vernier jaws 22 are also curved in the same shape as the inner jaws 11 and 21, so that the front ends 12a and 22a of the two jaws 12 and 22 are formed. ) Can be measured in contact with the outer diameter or the outside of the object to be measured.

According to the vernier caliper of the present invention made as described above, the process of measuring the measurement object in which the cross-sectional shape has an industrial cross-section or a deep groove is formed and the cross section is not exposed to the outside is continuous. A description with reference to 2b is as follows.

As shown in Fig. 2A, the measurement of the thickness t of the columnar portion 31 of the member 30 in the member 30 in which the object to be measured has an industrial cross section is first performed by the mother jaw 12 and the vernier jaw ( The tip 12a, 22a of 22 is extended so that it may not be caught by the wing part 32 of the industrial-shaped member 30, and then both tip 12a, 22a will pass through the wing part 32, and both tip 12a may be carried out. , 22a) is retracted until it contacts the pillars 31 of the two jaws 12 and 22.

That is, when the two ends of the mother jaw 12 and the vernier jaw 22 are in contact with the pillar portion 31, the opening amounts of the two ends 12a and 22a become the thickness t of the pillar portion 31. .

Here, when the tip 12a, 22a of the two jaws 12, 22 is retracted and the thickness of the pillar portion 31 of the industrial member 30 is measured, the two jaws 12, 22 are curved in a curved shape. Therefore, the measurement work can be easily performed without being interfered with the wing portion 32 having a larger width than the pillar portion 31.

On the other hand, as shown in Fig. 2B, the method for measuring the groove width d of the member 40 in which the deep grooves 41a and 41b are formed is the tip 11a of the mother inner jaw 11 and the vernier inner jaw 21. , 21a is reduced to a size enough to allow the two inner jaws 11 and 21 to enter into the grooves 41a and 41b, and then the two inner jaws 11 and 21 are inserted into the grooves 41a and 41b. By extension.

Thus, when the two inner jaw tips 11a and 21a entering the grooves 41a and 41b are no longer expanded in contact with the wall surfaces of the grooves 41a and 41b, the ends 11a and the two inner jaws 11 and 21 are not expanded. The opening amount of 21a) becomes the groove width d of the measurement object 40.

Here, even when the tip ends 11a and 21a of the two inner jaws 11 and 21 are expanded, the groove width d of the measured object 40 in which the deep grooves 41a and 41b are formed is measured. 21 is bent, so that the projections 42a and 42b around the grooves 41a and 41b can be easily accessed without interference and can be measured.

As described above, according to the vernier caliper according to the present invention, even when a cross section is formed like an industrial shape or a step is formed or a deep groove is formed, the corresponding jaw can be easily approached to measure the dimensions. You can get it.

In addition, since the measurement work is performed by accessing the jaw directly to the part that needs to be measured, there is no accumulation of errors generated during indirect measurement, and thus the effect of obtaining a precise measurement value can be obtained.

Claims (1)

It is inserted into the main chuck 10 having the mother inner jaw 11 and the mother jaw 12 up and down, and the chuck 20 of the vernier inner jaw 21 and the vernier jaw 22 slides so as to slide the object under test. In the vernier caliper which can measure dimensions, The dimensions can be measured by the opening width between the ends 11a, 21a; 12a, 22a of the two jaws 11, 21; 12, 22 corresponding to each other in the jaws 11, 12, 21, 22, From the tips 11a, 21a; 12a, 22a, the portions leading to the main body 10 and the body of the subchuck 20 are curved in a curved shape to prevent interference with the ends or jaws around the measurement part. Vernier caliper characterized by.