RU76708U1 - DEVICE FOR MEASURING THICKNESS OF SURFACE CONDUCTIVE LAYER OF PRODUCT - Google Patents

Abstract

The inventive utility model relates to the field of engineering, mainly to the creation of instruments and devices for measuring and controlling the quality of the surface layer of products after machining.

The technical result is achieved by the fact that in the device two spring-loaded measuring electrodes are mounted in movable cages, two spring-loaded current-supplying and two spring-loaded measuring electrodes are perpendicular to the surface of the cover, and two spring-loaded measuring electrodes are in movable cages.

Description

The inventive utility model relates to the field of engineering, mainly to the creation of instruments and devices for measuring and controlling the quality of the surface layer of products after machining.

A four-probe device for measuring the thickness of the surface layer is described in the book by A. V. Chistyakov, V. I. Butenko, Y. A. Gogolev “Optimization of operational and technological processes in mechanical engineering”, Rostov-on-Don, publishing house RSU, p. 22-24. consisting of a housing, two current-carrying and two measuring electrodes installed in a dielectric housing with a cover perpendicular to the surface of the cover, terminals and clamps attached to the housing with screws.

A sign of the similarity of the considered device for measuring the thickness of the surface layer with the claimed utility model is the presence of a dielectric housing, two measuring electrodes, two current-carrying electrodes, terminals and clamps.

The reasons that prevent the use of the considered device for measuring the thickness of the surface conductive layer are its bulkiness and low measurement accuracy due to the peculiarities of the flow of electric current in the surface layer of the processed products.

A device for measuring the thickness of the surface conductive layer of the product (AS No. 1783287, class G01B 7/06, 1992, bull. No. 47) containing a dielectric housing and a cover, two spring-loaded current-conducting electrodes installed in the housing at an angle to the surface housings, two spring-loaded measuring electrodes,

installed in the housing perpendicular to its surface, terminals, return springs and clamps.

For the considered device for measuring the thickness of the surface conductive layer of the product, the signs coinciding with the essential features of the claimed utility model are the presence of a dielectric housing, two current-carrying and two measuring electrodes, terminals, return springs and clamps.

The reason that prevents the measurement of the thickness of the surface conductive layer of the product using a known device is its low accuracy, due to the weak contact stiffness of the measuring electrodes with the surface being studied due to roughness and the lack of adjustment for the actually measured thickness of the conductive layer of the product.

The closest technical solution is a device for measuring the thickness of the surface conductive layer of the product (patent No. 2167392, class G01B 7/06, G01R 27/16 2001, bull. No. 47), comprising: a dielectric housing and a cover attached to the housing by screws, two spring-loaded current-carrying electrodes placed in the housing at an angle to its surface, two spring-loaded measuring electrodes installed in the middle of the housing at an angle to its surface, terminals, return springs, clamps attached to the housing with screws, sources Power is connected to the spring-current-carrying electrodes and a measuring device connected to the spring-loaded measuring electrodes.

Signs that coincide with the essential features of the claimed utility model: dielectric housing, two spring-loaded current-supplying electrodes, two spring-loaded measuring electrodes, terminals, return springs, clamps, a power source connected to the spring-loaded current-supplying electrodes and a measuring device connected to the spring-loaded measuring electrodes.

The disadvantage of the described device for measuring the thickness of the surface conductive layer is its low accuracy, due to the fact that during grinding there is a sufficiently large variation in the electrical resistance of the material of the surface layer due to the presence of a large number of local burn zones on the surface. The device does not have sufficient accuracy, since the measurement by this device does not take into account the inconstancy of the instantaneous temperature in the cutting zone; inconsistency of cutting force; different state of the working surface of the circle on the periphery or end face (depending on the grinding pattern).

The purpose of the claimed utility model is to increase the measurement accuracy.

The technical result consists in the fact that two spring-loaded current-supplying and two spring-loaded measuring electrodes are perpendicular to the surface of the cover, and two spring-loaded measuring electrodes are in movable clips.

To achieve a technical result, a device for measuring the thickness of the conductive layer of the product, containing a dielectric housing and a cover, two spring-loaded current-conducting electrodes, two spring-loaded measuring electrodes, terminals, clamps, return springs, a power source connected to the current-carrying electrodes and a measuring device connected to the measuring electrodes is supplemented by the fact that two spring-loaded current-conducting and two spring-loaded measuring electrodes are perpendicular to the surface STI cover, two spring loaded measuring electrodes are in movable cages.

The inventive utility model is illustrated by the drawings shown in figures 1-4. Figure 1 shows a General view of a device for measuring the thickness of the surface conductive layer of the product; figure 2 shows a circuit diagram of a connection device for measuring the thickness of the surface conductive layer of the product when

its use; figure 3 is a calibration graph of a device for measuring the thickness of the surface conductive layer of the product; figure 4 is a graph of the distribution of electrical resistance at the base length of the surface of the part.

A device for measuring the thickness of the surface conductive layer of the product (Fig. 1) consists of a housing 1, with a scale applied on the upper surface, in which two spring-loaded current-supplying electrodes 2 and two spring-loaded measuring electrodes 3 located in movable clips 4 of dielectric material, are installed 5 of a dielectric material attached to the housing by screws 6, return springs 7 and clamps 8, attached to the housing 1 by means of screws 9 and terminals consisting of washers 10 and nuts 11.

A device for measuring the thickness of the surface conductive layer of the product operates as follows. Connecting a device consisting of a housing 1 with a cover 5 attached to it with screws 6, to spring-loaded current-supplying electrodes 2 inserted into return springs 7, is carried out by terminals consisting of washers 10 and nuts 11 from a direct current source G (Fig. 2), for example, a power source B5-47, through a rheostat R, a millivoltmeter mV, which can be used as an instrument Ml 202, a package of switches P ₁ reference rheostat R _et. From the measuring electrodes 3 inserted into the return springs 7 located in the movable clips 4, voltage is applied to the DC potentiometer through a packet switch P ₂ (not shown in FIG. 2). The device is fixed on the surface of the test material using clamps 8, mounted on the housing 1 with screws 9. Previously, the device is calibrated with the construction of the corresponding schedule (figure 3). After measuring the electrical resistance at several points on the base length of the surface, a more accurate graph of the distribution of electrical resistance on the base length of the surface of the part is constructed (figure 4).

Claims (1)

A device for measuring the thickness of the conductive layer of the product, containing a dielectric housing and a cover, two spring-loaded current-conducting electrodes, two spring-loaded measuring electrodes, terminals, clamps, return springs, a power source connected to the current-carrying electrodes and a measuring device connected to the measuring electrodes, characterized in that two spring-loaded current supply and two spring-loaded measuring electrodes are perpendicular to the surface of the cover, and two spring-loaded KSR Control electrodes are in movable cages.