RU2722341C1 - Vernier caliper - Google Patents

Abstract

FIELD: measuring equipment.SUBSTANCE: present invention relates to measurement equipment, particularly to vernier calipers intended for measurement of external and internal dimensions of parts of "shaft" or "hole" type, as well as external and internal dimensions of parts of another shape. Claimed vernier caliper two-sided consists of a bar with a main scale, a frame with a vernier scale mounted to move along the rod, two jaws and a device for fine installation of the frame. At that, the said vernier calipers are additionally equipped with two elastic elements installed in the vernier caliper with the possibility of their selection from the set of elastic elements of a certain length and characteristics in accordance with the range of measured sizes and conditions, whether these dimensions are external or internal, wherein one of the resilient elements is located on the back side of the vernier caliper in parallel to the axis of the rod and provides a force closure between the bar and the vernier scale frame, and second resilient element is located between jaws for measurement of external or internal dimensions with possibility of providing power closure between said jaws.EFFECT: technical result consists in improvement of measurement accuracy of both external and internal dimensions due to stabilization of measuring force, as well as in increased efficiency of measurement process.1 cl, 4 dwg

Description

The invention relates to measuring equipment, in particular to calipers, designed to measure the external and internal dimensions of parts such as "shaft" or "hole", as well as the external and internal dimensions of parts of a different shape.

Calipers are known [1, FIG. 1, 2 and 4], consisting of a rod with a scale, a frame moving along the rod and jaws with flat measuring surfaces for measuring external dimensions. Due to the simplicity and ease of use, these types of calipers are widely used both in small-scale and mass production. Calipers of these types are also used in large numbers in domestic conditions. At the same time, these type calipers have a serious design flaw, which is as follows. During the measurement, the frame along the bar is moved using (usually) the thumb of the operator’s right hand. Moreover, from measurement to measurement, the measuring force is different, even when performing measurements by one operator. Naturally, for different operators when measuring the same size of the same part, the measuring forces can vary significantly. That is, the measurement results from measurement to measurement are obtained with a large error depending on the subjective factors of the operator performing the measurement. The importance of this provision is also indicated in the source [2, p. 13, first paragraph from the bottom]. Thus, in the measurement process, in order to reduce the measurement error, it is necessary to stabilize the measuring force within certain limits, for example, as was done in smooth micrometers [3, clause 2.1.1.2] with a ratchet (friction clutch) within 5-10 N, and the oscillation measuring force for micrometers of all types should not exceed 2 N.

Closest to the technical nature of the present invention is a two-type caliper type II [1, Fig. 3]. This caliper is additionally equipped with a device for fine-tuning the frame. The mechanism of thin installation of the frame [4, p. 86, Fig. 57] consists of a clamp connected to the frame using a micrometer screw and nut. With this device, a small feed of the frame. This design also does not solve the problem of reducing the measurement error by stabilizing the measuring force, since the frame moves along the rod by manually rotating the microscrew. In commercially available calipers, the microscrew has small dimensions (with a diameter of only 10 mm), which is very difficult to move the frame along the rod again does not allow to stabilize the measuring force, reduces the performance of the measurement process.

Thus, the well-known commercially available calipers have a significant drawback, which is the instability of the measuring force from measurement to measurement, which is a source of increasing random error and the task is to reduce the error of the measurement results by stabilizing the measuring force by further improving the design of the caliper.

The aim of the invention is to improve the accuracy of the measurement results with a caliper of both external and internal dimensions by stabilizing the measuring force using a flexible element located on the back of the caliper or a flexible element located between the jaws to measure the external and internal dimensions, as well as improving the performance of the measurement process .

In FIG. 1 (main front view) shows a commercially available vernier caliper, where the following designations are accepted: 1 - a bar with a main scale; 2 - frame with vernier scale; 3 - clamping element; 4 - frame fixing screw; 5 - frame; 6 - screw mechanism for thin installation of a frame with a vernier scale; 7 - sponges with flat and cylindrical surfaces for measuring external and internal dimensions, respectively; 8 - sponges with edge measuring surfaces for measuring external dimensions; OO - line of symmetry of the rod.

In FIG. 2 (general front view) shows the proposed vernier caliper, with an installed elastic element located between the jaws to measure the external and internal dimensions and used when measuring internal and external dimensions, where the following designations are used: 9 - an elastic element that creates a force that spreads or brings together the jaws 7 (8), the remaining designations are the same as in FIG. 1.

In FIG. 3 (rear view) shows the proposed vernier caliper, where the following notation is used: 10 - an elastic element that creates a force spreading the jaws 7 (8) in different directions when measuring internal dimensions and bringing it together when measuring external dimensions; 11 - the rods of the fastening of the elastic element on the rod and frame with a vernier scale; the remaining designations are the same as in FIG. 1 and 2.

In FIG. 4 (top view) shows the proposed vernier caliper, the symbols are the same as in FIG. 1, 2 and 3.

For simplicity, the boom scale and vernier scale of the caliper frame are not shown.

The invention consists in the following. During the measurement process, the measuring force must be provided within certain limits, for example, for smooth micrometers [5, clause 2.1.1.2.] This force must be strictly no less than 5 and no more than 10 N. From this it can be seen that the accuracy of the measurement results is greatly influenced stability of measuring effort. For MK type smooth micrometers, to stabilize the measuring force, a ratchet (friction clutch) is structurally provided, which should provide a measuring force in the range of 5-10 N in any measuring range. For a ShTs caliper, for example, ShTs-II-250-0.05 GOST 166 -89 and other types, a device stabilizing the measuring force is not structurally provided. For this reason, when measuring the dimensions of both external and internal calipers, the measuring force during the measurement process is not controlled or stabilized, which causes a large spread of measurement results, even when performing measurements of the same size and the same operator. That is, when measuring dimensions with a caliper, one of the sources of the components of random errors, moreover, prevailing, are the subjective features of the operator performing the measurements. Whereas with a MK type micrometer, the presence of a ratchet excludes the influence of the subjective characteristics of the operator on the measuring force, no matter how much the operator twists the ratchet during the measurement, the ratchet still provides a measuring force within 5-10 N. Therefore, the task is to make a caliper type ШЦ constructively supplemented by a device that allows to stabilize the measuring force when performing measurements of both external and internal dimensions. The problem is solved as follows.

The commercially available caliper type SHZ (Fig. 1) consists of the elements listed in Figs. 1, and with such a design, the caliper cannot provide a stable measuring force and the measurement results are obtained with a large error.

To stabilize the measuring force in the design of the proposed caliper added (installed) elastic element 9, for example, a spring (Fig. 2). An elastic element is installed between the jaws 7 along the axis AA, which is parallel to the axis of symmetry O-O of the rod. When measuring the external dimensions, for example, the diameters of the shafts, an elastic element is installed, which creates a force aimed at the convergence of the jaws 7 (8). When measuring the internal dimensions, for example, the diameters of the holes, an elastic element is installed that creates a force aimed at disconnecting the jaws 7 (8).

In addition to the elastic element 9, a second elastic element 10 is installed coaxially with the axis of symmetry O-O of the rod 1 from the rear side of the caliper (Fig. 3). Similarly to the elastic element 9, when measuring the outer dimensions, for example, the diameters of the shafts, an elastic element 10 is installed, which creates a force directed towards the convergence of the jaws 7 (8). When measuring the internal dimensions, for example, the diameters of the holes, set the elastic element 10, which creates a force directed to the separation of the jaws 7 (8). The elastic element 10 creates a constant power circuit between the rod 1 and the frame 2 with a vernier scale. The elastic element 10 is mounted on the rods 11.

The elastic elements 9 and 10 can be used individually and together. When used together, they create measuring forces directed in one direction, that is, to disconnect the jaws 7 (8), or to approach. That is, at the same time their measuring efforts add up. This design eliminates the bias of the frame 2 during the measurement process and stabilizes the measuring force.

The figure 4 gives a visual representation of the design of the proposed caliper and the relative location of the elastic elements 9 and 10.

With the proposed caliper design using elastic elements, it is difficult to provide a constant measuring force for a wide range of measured sizes using an elastic element of the same length and characteristics, for example, the ShTs-II-250-0.05 caliper GOST 166-89 allows you to measure sizes within 0- 250 mm. Therefore, a vernier caliper is equipped with a set of elastic elements of appropriate lengths and characteristics, allowing to provide a constant measuring force within specified limits for a wide range of measured sizes.

Measurement of both external and internal dimensions is carried out by a known method in the following sequence. First, the corresponding elastic elements 9 and 10 are selected and mounted on the caliper from the existing set, taking into account the measured size and taking into account which size is measured, external or internal. Then, using the operator’s thumb, the jaws are pushed apart and the measured size is placed between the jaws 7 or 8 (Fig. 2) when measuring the outer dimensions. Then the working surfaces of the jaws are smoothly brought into contact and the thumb is removed, while the elastic elements 9 and 10 (Fig. 3) tightly contact the working surfaces of the jaws with the surface of the part, for example, a shaft with a certain measuring force. Then read the caliper.

When measuring the internal dimensions, for example, the diameters of the holes, the elastic elements 9 and 10 are selected, which create a spreading force, the cup 7 and 8 (Fig. 2). Then, cylindrical measuring surfaces are arranged for measuring the internal dimensions of the jaws 7 (Fig. 2) and, using the thumb of the operator, the cylindrical measuring surfaces are smoothly brought into contact to measure the internal dimensions with the surface of the measured hole and the thumb is removed. In this case, the elastic elements 9 and 10 (Fig. 3) tightly contact the working surfaces of the jaws 7 to the surface of the measured hole, creating the necessary measuring force. Then read the caliper.

The technical effect consists in increasing the measurement accuracy of both external, for example, shaft diameters, and internal dimensions, for example, hole diameters, by stabilizing the measuring force, as well as increasing the productivity of the measurement process.

Sources of information

1. GOST 166-89 Calipers. Technical conditions

2. Fundamentals of metrology and theory of accuracy of measuring devices. Korotkov V.P., Taits B.A., M .: Publishing house of standards, 1978, 352 p.

3. GOST 6507-90 Micrometers. Technical conditions

4. Ivanov AA, Technical measurements (with laboratory practice). M., Publishing House Kolos, 1964. 488 p. (textbooks and textbooks. manuals for higher agricultural schools. institutions).

5. GOST 6507-90 Micrometers. Technical conditions

Claims (1)

Two-sided caliper, consisting of a bar with a main scale, a frame with a vernier scale, mounted for movement along the bar, two jaws and a device for fine-tuning the frame, characterized in that it is additionally equipped with two elastic elements installed in the caliper with the possibility of choosing from a set of elastic elements of a certain length and characteristics in accordance with the range of measured sizes and conditions whether these dimensions are external or internal, while one of the elastic elements is located on the back side of the caliper parallel to the axis of the rod and provides power closure between the rod and the frame with a vernier scale, and the second elastic element is located between the jaws to measure the external or internal dimensions with the possibility of providing a force circuit between these jaws.

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