SU759239A1 - Apparatus for centring parts with non-circular cross section - Google Patents

Description

The invention relates to a machine tool, namely, devices for centering, turning parts with clamping chucks, providing the mixing of parts; relative to the axis of rotation of the spindle, and can be used to center parts ⁵ with a non-circular cross-section, in particular precious stones, jewelry diamonds.

A device for processing products eccentric, consisting of a faceplate with za- olive with cartridge ¹⁰ and the counterweight with further radially displaceable counterweight, the first counterweight faceplate interconnected by a pin minutes radial groove (1). ¹⁵

The disadvantages of this device are the vibration of the cartridge at high speeds of rotation due to the mixing of the center of gravity of the cartridge, as well as the need for additional alignments in the process.

A device for centering parts of a non-circular cross-section, mainly jewelry diamonds, containing

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spindle, floating chuck with radially moved faceplate and counterweight and collet chuck, and a mandrel for the part [2].

A disadvantage of this device is low precision centering, since the centering is done manually.

The purpose of the invention is to improve the accuracy of centering.

This goal is achieved by the fact that the device for centering parts of a non-circular cross-section, mainly jewelry diamonds, contains a spindle, a floating cartridge with radially moved faceplate and counterweight and a collet clamp, and a mandrel for the part, equipped with a photoelectric probe with a source and radiation receiver, stepper motor, screw transmission, electromagnetic pusher, power supply, amplifier and control unit, and the photoelectric probe is mechanically connected to the stepper motor Without a screw transmission, and the radiation source, the stepping motor and the electromagnetic pusher are electrically connected to the power supply, the output of the radiation receiver through the amplifier is connected to the input of the control unit, the outputs of which are connected to the electromagnetic pusher and the stepping motor.

FIG. 1 shows a floating cartridge with detail, cut; in fig. 2-functional diagram of the device for centering.

A device for centering parts of a non-twisted cross-section includes a machine spindle 1, a floating cartridge body 2, a faceplate 3, a collet chuck 4, a mandrel 5, a finger 6, spherical bushings 7, a counterweight 8, a photoelectric probe 9, a radiation source 10, a radiation receiver 1.1, a collimator 12, power supply unit 13, probe guides 14, screw transmission 15, stepper motor 16, handwheel 17, amplifier 18, control unit 19, electromagnetic pusher 20, indicator light 21, part 22.

The device works as follows. .

Before centering, the part 22 is fastened on the mandrel 5, for example, by an adhesive method, and then the last collet clamp 4 is fixed in the cartridge. At the same time, the axis Οι of the circle of maximum radius mentally inscribed in the non-cool base of the part is offset from the axis 0 of the rotation of the spindle 1 (Fig. 2). FIG. 2 'thick lines depict the contour of the cross section of the part before centering, thin - after its end. The handwheel 17 manually performs the installation movement of the probe 9. The power supply unit 13 is turned on. Slowly turn the spindle 1 with the chuck part. At the beginning, when the beam does not overlap the generator part, it hits the receiver 11, in which an electrical signal is generated. Amplified, this signal provides the response unit 19 control. The chain of the pusher coil 20 closes and the pusher with a frequency of 50 Hz strikes the peripheral part of the faceplate 3, shifting it together with the axis 0 ^ details to the axis 0 of the spindle rotation. At the same time, the control unit 19 turns on the stepper motor 16, which through the screw gear 15 mixes the probe 9 to the axis of rotation of the spindle. When the probe approaches the part at a sufficient distance, the parts of the base of the part furthest from the axis of rotation of the spindle will interrupt the beam for a while. During these periods of time in the receiver 11 there will be no signal, as a result, the stepping motor is turned off for this time, the movement of the probe stops; 20 pusher coil

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The faceplate 3 does not mix to the axis of rotation. With further turning of the part — due to its non-circular cross section, the beam again reaches the receiver 11 and the process of discrete mutual approach of the axis 0 ^ detail and the probe 9 to the axis 0 of rotation continues. At these times, the indicator light 21 informs the worker about the continuation of the centering process. The pitch of the helical gear 15 and the parameters of the stepper motor 16 are such that the displacement of the probe 9 and the faceplate 3 under the action of the pusher 20 are equal. When the faceplate 3 is displaced through the spherical bushings 7 and the finger 6, the counterweight 8 mixes in the opposite direction, reducing the spindle vibrations during rotation. The centering process is completed when, within the full rotation of the part, the beam does not reach the receiver.

This turns off the stepper motor 16 and the pusher 20, the indicator 21 stops the supply of light signals. >,

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Claims (1)

Claim A device for centering parts of a non-twisted cross-section, mainly jewelry diamonds, containing a spindle, a floating cartridge with radially moved faceplate and counterweight and a collet clamp, and a mandrel for the part, characterized in that, in order to improve the accuracy of centering, it is equipped with a photoelectric probe with a source and radiation receiver, stepper motor, screw gear, electromagnetic pusher, power supply, amplifier and control unit, and the photoelectric probe is mechanically connected The radiation source, the stepping motor and the electromagnetic pusher are electrically connected to the power unit, the output of the radiation receiver through the amplifier is connected to the input of the control unit, the outputs of which are connected to the electromagnetic pusher and the stepping motor.