RU2159920C1 - Device measuring real dimensions of outer surfaces and radii of spherical articles - Google Patents

Abstract

FIELD: instrumentation, metrology, mechanical engineering. SUBSTANCE: device measuring parameters of outer surfaces and of radii of spherical articles has base, object table mounted for vertical movement, spindle of standard rotation, bearing member carrying axial reading head mounted for movement along axis of object table and for rotation around measured part. Device also includes rest mounted for contact with object table with plane matching rotation axis of axial reading head for precise adjustment of device with nominal dimension of parameter of surface and radius of spherical article and conical ring whose bigger base faces object table and axis of table coincides with axis of object table mounted for rotation around its axis. Holder of conical ring can turn around axis for fixation. Object table can be fitted with pneumatic gripper to fix measured article. Proposed invention makes it possible to take real dimensions of parameters of outer surfaces and of radii of spherical articles by direct measurement with high degree of precision and authenticity, to evaluate measurements by deviations from specified nominal dimension of parameter of surface and radii of spherical article with use of high- precision standard plane-parallel end length measures and reading units by direct measurement, to expand application field of non-standard measurement means not embraced by State standards. EFFECT: simplicity of adjustment of device and of its handling, high economical effect since there is no necessity for manufacture and usage of templates. 2 cl, 1 dwg

Description

 The invention relates to the field of technology of mechanical engineering and instrumentation, to the technique of metrological support, and in particular to means for measuring the actual dimensions of the parameters of the outer surfaces and radii of spherical products.

 The predominant area of its application is the design and manufacture of universal high-precision devices designed to measure the actual dimensions of the parameters of the outer surfaces and radii of spherical products, including optical, precision, using standard measuring instruments by direct measurement.

 A known method of controlling concave and convex curved surfaces with radius templates (GOST 4126-66). The control is carried out by interfacing the template with the surface to be checked: by the size and uniformity of the lumen they judge the quality of processing (Berkov V.I. Technical measurements. -M .: Higher school, 1977, p. 56). Spherical surfaces are a variety of such surfaces and are controlled in a similar way, although the method of controlling their radius patterns is very complex and especially difficult. Existing universal measuring instruments are not suitable for the direct control of such surfaces. However, the patterns do not allow measurements of the actual dimensions of surface parameters and radii of spherical products. The process of manufacturing templates and counter-patterns with a curved profile is also very complicated and difficult, while they have the property of losing and changing their parameters during storage. Aging, warping, corrosion, nicks, wear, temperature effects and other factors do not allow for reliable estimates of their measurements.

 It is known auth. St. N 122881, G 01 B 05/22 (publication BI N 19, 1959), in which a device for checking the parameters of a spherical product and the surface of a body of revolution, having a tail hinged part equipped with transverse slides and used for mounting on the machine or outside the machine, is claimed. A bracket is pivotally connected to the tail part, provided at the ends with center trunnions located on the transverse slide for the inner rotary bracket that carries the indicator on it in order to precisely align the point of intersection of the axis of the indicator tip and the axis of rotation of the inner bracket with the center of the spherical product or when controlling the body surface rotation - with the base from which the coordinates of the points of this surface are given.

 These methods of measuring the dimensions of the parameters of the outer surfaces of spherical products consist in comparing their parameters with the corresponding parameters of the radius patterns and spherical standards.

 The disadvantage of these solutions, in addition to the complexity of the design, is the desire to measure the parameters of spherical products not from the origin of deviations - the nominal size of the spherical product, but from a template that replaces the nominal size of the spherical product.

 A known method for determining the parameters of surfaces (ed. St. N 238170, publication BI N 9, 02.20.69) on a three-coordinate measuring device, which consists in finding the coordinates of the centers of the circles of the measured product, formed by the intersection of a controlled spherical surface with planes passing through its center, and the magnitude of the range of the indicator when turning it around the axis of rotation determines the non-circularity of these circles, and their radius is determined by measuring the distance between the tip of the contact probe and its axis of rotation Eden.

 The known device for measuring the radii of curvature of conjugated spherical surfaces, selected as a prototype of the claimed device (ed. St. N 338774, publication BI N 16, 05/05/72), contains a base, a subject table, an exemplary rotation spindle, bearing a crank with a measuring head, on which a measuring probe is installed, interacting with the controlled surface. The measuring head is made rotatable around an axis parallel to the axis of the spindle model rotation and is equipped with a second measuring probe.

 A disadvantage of the known method and device is that they do not provide high quality measurements of the dimensions of surfaces and radii of spherical products, since the readings, fixing the coordinates of movement of the products, as well as calculating the distances between the probe and its axis of rotation using the formula and aligning the center of the spherical surface with the spindle axis of the model rotation, the alignment of the axis of the measuring probe with the axis of the product is carried out by the installation movement of the controlled product along three coordinate axes.

 Both the axis and the center are spatial concepts, therefore it is impossible, or theoretically possible, to combine them by moving with a device having elements for installation movement along three coordinate axes. In addition, the presence of a large number of elements for installation movement complicates the design of the device, and does not allow with high accuracy, if at all, to carry out all of the above measurement operations.

 The need for multiple removal and installation of controlled products on the device requires its multiple settings, which in some cases entails the accumulation of measurement error.

 Wrong choice of the reference point of measurements, i.e. replacing a nominal size when setting up the device with a standard, a mating surface, etc., inevitably leads to an incorrect assessment of the measured parameters, and the values measured in this way cannot be recognized as valid and reliable. The device does not allow measurements of surface parameters of products such as a spherical layer, spherical segment, stepped spherical surfaces, etc.

 The technical task to be solved is the development of a device for measuring the actual dimensions of the parameters of the outer surfaces and the radii of spherical products using standard measuring instruments by direct measurement and devoid of these disadvantages.

 The technical result is high measurement accuracy, solving for the first time the problem of measuring the actual dimensions of the parameters of the outer surfaces and radii of the spherical products, evaluating the measurements by deviations from the given nominal size of the surface parameter and the radius of the spherical product using only high-precision standard plane-parallel end measures of length and reading devices by direct measurement, expansion of the scope, exclusion from practice of the use of non-standard measuring instruments not covered by civil defense T, easy adjustment device and its application. Great economic effect, since there is no need to make and use templates.

 The problem is solved as follows.

 The proposed device for measuring the actual dimensions of the surface parameters and radii of spherical products is made of structural links and elements having a minimum number of connections.

 The axis of the reference axial head in the vertical plane is constantly aligned with the axis of the object table. The device is adjusted to the nominal size of the outer radius of the spherical product by plane-parallel end measures of length (GOST 9038-83) from the axis of the spindle of the element carrying the head to its tip (probe). For this purpose, for the convenience and speed of this operation, the plane of the object table is used as the initial intermediate base for installing on it a set of plane-parallel end measures of length equal to the nominal size of the outer radius of the spherical product. For this purpose, the plane of the object table is aligned with the horizontal plane of the axis of the spindle along the stop mounted on the spindle of the element carrying the reference axial head. The removable emphasis has a flat cut. The cut plane is aligned with the horizontal plane of the spindle axis. The installation of a spherical product in a coaxial position with the axis of the object table is carried out by a folding self-centering device made in the form of a ring mounted in the horizontal plane with an internal calibrated cone, the axis of which in the working position is aligned with the axis of the reading axial head and the axis of the object table, and the large base of the cone faces the plane of the subject table. The object table is mounted with the possibility of rotation around its axis and movement in a vertical plane, and is also equipped with a vacuum suction cup for mounting spherical products on it after installing them in a position coaxial with it.

 The invention is illustrated by the drawing, which shows a diagram of a device for measuring the actual dimensions of the parameters of the outer surfaces and radii of spherical products.

 A device for measuring the actual dimensions of the parameters of the outer surfaces and the radii of the spherical products contains a base 1, supporting the object table 2, equipped with elements for installation movement in a vertical plane and rotational around its axis with a vacuum suction cup for mounting spherical products on it after installing them in alignment with it position. In the base 1, a bracket 3 is fixed, bearing in its nests on two mounted and radially arranged, vertically movable racks 4 of different lengths that can be moved in a vertical plane, a tiltable holder 5 with a ring 6 mounted on it with an internal calibrated cone, horizontally located, the axis which in the working position is combined with the axis of the object table 2 and the axis of the reading axial head 10, with a large base facing the plane of the object table 2, as well as the spindle 7, equipped with nny worm gear and limb with an angular scale (not shown) carrying poluskobu 8 and the carriage 9 with the reference axis 10. In the spindle head 7 is mounted a removable stopper 11 having a flat surface, which is aligned with the horizontal plane of the spindle axis plane.

 A device made in accordance with the technical solution works as follows.

 The reclining self-centering device is withdrawn from the zone of the plane of the object table 2 by withdrawing from the socket of the bracket 3 a shortened rack 4, turning it outside the zone of the plane of the table by turning in its socket on its axis another elongated rack 4 by any angle, which provides convenience for work. A removable stop 11 is mounted on the spindle 7. Moving the object table 2 in a vertical plane, it is supported in the shear plane of the stop 11 until their planes are aligned. A set of plane-parallel end measures of length with a size equal to the nominal size of the outer radius of the controlled spherical product is mounted on the object table 2. Moving the carriage 9 with the readout axial head 10 until its tip (probe) comes into contact with a set of end measures of length installed on the object table in contact with the stop 11, provide a power reserve of the tip for possible deviations of the measured product and record (record) the readings of the readout axial heads and secure the carriage 9 in this position. Lower the object table 2 to a position convenient for installing a spherical product on it. The end measures of length are removed from the table, and also the emphasis 11 is removed from the spindle 7. The spherical product is installed in a position coaxial with the object table 2 by a self-centering device, setting it into working position by introducing a shortened rack 4 into its bracket nest 3 and basing the cone of the ring 6 on spherical surface of the product. In this position, with the help of interchangeable magnets or a vacuum suction cup, the product is fixed on the object table 2. The self-centering device is removed as described above from the zone of the spherical surface of the product and the plane of the object table 2. By moving the object table 2 together with the spherical part in a vertical plane, the latter is brought into interaction by a spherical surface with a tip by a counting axial head, and the half-bracket 8 carrying it rotates around its axis by an angle equal to the central angle of the spheres Cesky products, during which the readings of the reference axis of the head 10 are recorded (written). By turning the object table 2 about its axis at any angle with simultaneous, if necessary, moving it in a vertical plane, measurements are made of the dimensions of the parameters of any number of arcs of large circles of the product. Continuing the interaction of the tip of the reading axial head with the surface of the spherical product and ensuring the passage of its tip along all points of the arcs of the large circles of the product, they achieve the same testimony, which is a sign of the combination of the center of the arcs of the large circles of the product and the center of the arc of the big circle described by the tip of the reading axial head in space . When comparing the readings of the readout axial head with its readings recorded during adjustment (commissioning) using plane-parallel end measures of length, the actual dimensions of the surface parameters and the radii of the controlled product are evaluated and determined. They are determined by the dimensions of the parameters of the arcs of the large circles of the product and are estimated by the coincidence or difference (deviation) of their values from the size of the parameter of the arc of the large circle (the center of which is aligned with the center of the spherical product), described in space when interacting with the spherical surface of the product with the tip of the reference axial head with a fixed before measuring it, by indicating the size of the outer radius equal to the specified nominal size of the outer radius of the spherical product, measured by end measures from the axis of the spindle of the element carrying the reference axial head to its tip and rotated by an angle equal to the central angle of the sphere of the controlled product.

Thus, the present invention to a device for measuring the actual dimensions of the parameters of the outer surfaces and radii of spherical products:
1) simplifies the design of the device through the use of a minimum number of links and installation structural elements and connections; while dramatically increasing the accuracy of measurements;
2) allows you to use only standard measuring instruments, including high-precision plane-parallel end measures of length and counting axial heads pneumatic, inductive, electrical sensors, mechanical indicators, etc. with a division price from 0.01 to 0.0001 mm;
3) solves the problem of measuring the actual dimensions of the parameters of surfaces and radii of spherical products by direct measurement with a high degree of reliability;
4) there is no need to design and manufacture disposable expensive non-standard measuring instruments: templates, standards, samples, and allows you to remove the subjective factor in assessing the measured dimensions by these means;
5) increases labor productivity due to the ease of use and maintenance of the proposed measuring device;
6) expands the scope of the device: allows you to measure the size of the parameters of any external spherical surfaces, including spherical segments, spherical layer, stepped spherical surfaces, to carry out accurate incoming inspection of external supply products and products that were in use, as well as measure the dimensions of thin-walled spherical products and sectors on the mandrel;
7) allows for particularly accurate marking work on the surfaces of spherical products;
8) allows you to dramatically improve the quality of connections of spherical parts;
9) allows you to get a significant economic effect.

Claims (3)

 1. A device for measuring the external parameters of the surfaces and radii of spherical products, containing a base, an object table having the ability to move vertically, an exemplary rotation spindle, a bearing element on which an axial reading head is mounted with the ability to move along the axis of the object table and rotate around the measured part, characterized in that an emphasis is introduced into the device, having the ability to contact the object table with a plane coinciding with the axis of rotation of the axial reading head To fine tune the device to the nominal resolution setting surface and the radius of the spherical product, and mounted on the holder ring cone, the large base of which faces the object stage and the ring axis coincides with the axis of the object stage, rotatable around its axis.  2. The device according to claim 1, characterized in that the conical ring holder is rotatable around the existing axis with the possibility of fixation.  3. The device according to claim 1, characterized in that the subject table is equipped with a pneumatic gripper for fixing the measured product.