RU2456539C1 - Method of measuring deviation of planes from centre of outer spherical surface - Google Patents

Abstract

FIELD: physics.

SUBSTANCE: post on which a clamp is mounted is placed on an adjustment plane. A reading device is placed on a locator while providing the gauge rod a given reach in a conical hole in the locator. The locator is placed on the adjustment plane. The measurement object is placed with the spherical surface into the conical hole, wherein contact of the first measured plane with the gauge rod is provided. The clamp brought into the conical hole while simultaneously rotating the measurement object, thereby adjoining the working surface of the clamp with the second measured plane. A first reading is taken from the reading device and the clamp is removed. The measurement object is remounted on the locator. Operations associated with measurement of the location of the second measured plane are repeated. A second reading is taken from the reading device. Deviation values of the adjusted value of the distance from the measured planes to the centre of the spherical surface are determined from readings taken from the reading device, and from the half-difference thereof, nonsymmetry of the planes relative said centre is determined.

EFFECT: measurement of two parameters of relative positions of planes and the centre of a sphere.

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Description

The invention relates to measuring technique and can be used in mechanical engineering, mainly for measuring the distances and symmetry of the planes relative to the center of the outer spherical surface.

There is a method of measuring deviations from the symmetry of the keyway relative to the axis of the cylindrical surface, carried out by basing the object with a cylindrical surface in a prism and using the reading head placed on it, the object being rotated in the prism sequentially in both directions to the stop and the reading of the reading head, the axis of which coincides with the bisector of the prism, and the tip contacts the bottom of the groove being tested [Copyright certificate SU No. 800600, IPC G01B 5/24, 1981 (analog)].

However, this method has limited technological capabilities, since it allows you to measure only the deviation from the symmetry of the groove and only relative to the axis of the cylindrical surface.

Closest to the claimed one is a method of measuring deviations of the distance between the intersecting axes of the outer and inner cylindrical surfaces, which consists in placing the rack on the mounting plane, placing two measuring heads on the rack with the same outreach of the measuring probes with respect to the axis of the rack, and setting the base prism on the installation plane in a position in which the sectorless plane of said prism is perpendicular to the axes of the measuring probes and is located on a given at the distance from the axis of the rack, a centering mandrel is installed in the inner cylindrical surface of the measuring object, the measuring object is installed on the base prism with the outer cylindrical surface with the possibility of interaction of the centering mandrel with the measuring probes, the measuring object is rotated on the base prism to the position at which the readings of the measuring heads are , and the deviation of the desired distance is determined by the deviation of the reading of the measuring head from the set value [Pat t RU №2125707 C1, IPC: G01B 5/00, Bull. No. 3, 1999 (prototype)].

However, in this way it is possible to measure the distance only between the axes of the cylindrical surfaces and it is impossible to measure the parameters of the planes relative to the center of the spherical surface: distance and deviation from symmetry.

The present invention was based on the task of developing such a method that provides measurement of parts containing the outer spherical surface and planes of two location parameters: the distance from the planes to the center of the sphere and their symmetry with respect to the said center.

This is achieved by placing the rack on the mounting plane, installing the clamp on the rack, installing a reading device on the base element, providing its measuring probe with a predetermined extension in the conical hole of the base element, placing the base element on the mounting plane in a position in which the axis of the conical hole is perpendicular the working surface of the clamp, set the measurement object with a spherical surface in a conical hole, providing contact of the first measured plane the measurement object with a measuring probe, the clamp is brought to the measurement object and at the same time the measurement object is rotated in the base element, ensuring that the working surface adheres to the second measured plane, the first reading of the reading device is taken, the pressure is removed, the measurement object is reset in the conical hole, providing contact of the second measured plane with a measuring probe, repeat the supply of the clamp with the rotation of the measurement object in the base element, achieving a snug fit of the working surface a first measurement plane remove indication second reading device, determine the deviation from the set value of the measured distance to the plane of the spherical surface center indications reading device, and their half-- deviation from the symmetry plane with respect to said center.

Thus, due to other conditions for performing operations known on the prototype of the measurement object and using the measuring device, additional operations and the order of operations in the proposed method, in comparison with the prototype, the measurement of two parameters of the planes relative to the center of the spherical surface is provided.

The figure shows the measurement scheme of the proposed method.

The proposed method is as follows. On the mounting plane 1, place the rack 2, install the clamp 3 on the rack 2, install the reading device 5 on the base element 4, providing its measuring probe 6 with a predetermined departure in the conical hole 7 of the base element 4, place the base element 4 on the installation plane 1 in the position in which the axis of the conical hole is perpendicular to the working surface 8 of the clamp 3, set the measurement object 9 with a spherical surface 10 in the conical hole 7, providing contact of the first measured plane 11 9 KTA measurement with the measuring probe 6, the clamp 3 is fed to the measurement object 9 and simultaneously rotating the measurement object 9 in a conical bore 7. In these joint motions achieve abutment working surface 8 of the second clamp 3 with the measured plane 12. Read the first indication reading device ₁ Δ 5, the clamp 3 is retracted. Then, the measurement object 9 is reinstalled in the conical hole 7 so as to ensure that the second measured plane 12 contacts the measuring probe 6. The clamp 3 is repeated to supply rotation of the object 9 Measurements in a conical hole 7 for providing abutment of the working surface 8 with a first clamp 3 measured plane 11, remove the second reading Δ ₂ reading device 5. Determine the adjusted deviation from the distance values measured by the planes 11 and 12 to a spherical surface center 10 of indications Δ ₁ and Δ _{2 of the} reading device 5, and by their half-difference, the deviation from the symmetry of the planes relative to the center.

This ensures the measurement of two parameters of the planes relative to the center of the sphere.

The method can be used at engineering enterprises when measuring parts containing requirements for the relative positioning of structural elements in the form of planes and spheres.

Claims (1)

A method for measuring deviations of the planes relative to the center of the outer spherical surface, which consists in placing the stand on the installation plane, installing the reading device, providing the probe with a predetermined reach, placing the basing element on the installation plane, installing the measurement object on the basing element, and rotating the measurement object in the base element, take readings of the reading device, determine the deviation of the location according to the readings of the reading device, characterized in that after the rack is placed, a clamp is mounted on it, the reading device is mounted on the base element with the placement of its measuring probe in the conical hole of the base element, ensuring the axis of the conical hole to be perpendicular to the working surface of the clamp, when installing the measurement object, place it with a spherical surface in the conical hole providing contact of the first measured plane of the measurement object with a measuring probe, while rotating the measurement object, they are brought to it clamp, securing the working surface of the clamp to the second measured plane, after taking the first reading of the reading device, the clamp is withdrawn, the measurement object is reinstalled in the conical hole, providing contact of the second measured plane with the measuring probe, the clamp is repeated with the measurement object rotating in the base element, achieving the fit the working surface of the clamp to the first measured plane, take the second reading of the reading device, and when determining the location of Rendering reading device deviation are measured distance from each plane to the center of the spherical surface, and the readings on the semidifference - deviation from the symmetry plane with respect to said center.