SU1350496A1 - Photoelectric function displacement converter - Google Patents

Abstract

This invention relates to a measurement technique. The aim of the invention is to improve the accuracy and enhance the functionality due to the optical acquisition of the function and the derivative of the function of the movement during the registration of the analog signal. The converter contains a mirror modulation node 3 that is associated with an object, the shape of which corresponds to the conversion function. A pair of photosensors in 4, 5, mounted symmetrically to the light sensor 1 in the reflected light flux, allows to obtain two analog signals used by the function driver 8 and the signal generator 6 of the derivative signal. 1 3.p. f-ly, 1 ill. (L y 7 7 OO JV CP 4 CO O5 /

Description

The invention relates to a measurement technique and can be used to convert mechanical quantities, such as forces, angular and linear movements, into electrical

specific function of mechanical quantities.

The purpose of the invention is to improve the accuracy and enhance the functionality by optocoupler obtaining the function and the derivative of the function of the displacement during the registration of the analog signal.

The drawing shows a photoelectric transducer functional displacement.

The converter contains a light sensor 1 connected to the output of the correction unit 2 through the reflective upper part of the mirror modulation unit 3 optically connected to the photo sensor, the sensor 4 and the photo sensor 5. Each photo sensor is connected to one of the inputs of the derivative 6 of the derivative signal, output which is connected to terminal 7. The photo sensor 5 is also connected to the input of the imaging unit 8 of the function signal, the output of which is connected to terminal 9. The retro-reflective modulation unit 3 is made in the form of a variable-curvature disk connected to the object ohm

The Converter operates as follows.

Light sensor 1 connected to the unit. 2 correction emits light flux on the reflecting surface of the mirror modulation node 3. When the modulation node 3 rotates, in accordance with the change in its radius of curvature, the magnitude of the radiant flux reflected from the adjacent regions of the reflecting surface on the photosensor 4 and the photosensor 5 changes. From the photo sensor 5. it enters the input of the imaging unit 8, at the output of which a function signal from angular displacements is formed. The signal from the photo sensor 4 and the photo sensor 5 is fed to the inputs of the

Editor S. Patrusheva Order 5249/40

Compiled by E. Glazkova

Tehred L. Oliynyk Proofreader

M. Maksimishi

Circulation 677 Subscription

VNIIPI USSR State Committee

for inventions and discoveries 113035, Moscow, Zh-35, Raushsk nab., 4/5

Production and printing company, Uzhgorod, st. Project, 4

the rotator 6, at the output of which a signal is derived from the derivative of the angular displacement. Correction of the function and its derivative from the movement is carried out by the correction unit 2 by changing the current of the light sensor 1, thus changing the value of the radiant flux coming from the light sensor 1 to the photo sensor 4 and the photo sensor 5.

The signals from photosensors 4 and 5 are proportional to the values of the functions (converted at points shifted by a certain angle o (. It follows that the error of the device is inversely proportional to hs and, if necessary, can be reduced by increasing the radius of the modulation node and decreasing the distance nor between c, photosensors.

Claims (2)

1. A photoelectric functional displacement transducer comprising a light sensor, a mirror modulation unit installed along the light beam, and a photo sensor characterized in that in order to increase accuracy and enhance functionality, it is equipped with a second photo sensor, a correction unit, a function shaper, a signal shaper derivative, the light sensor is connected to the output of the correction unit, the photo sensors are located in the course of the light rays reflected from the mirror modulation node symmetrically the axis of the light sensor, one photo sensor is connected to the input of the signal conditioner function and to the first input signal generator of the derivative, the second input of which is connected to the other. the photo sensor, the shape of the modulation node associated with the object, corresponds to the conversion function. 2. The converter according to claim 1, is about the fact that the mirror modulation node is made in the form of a disk of variable radius. M. Maksimishinets