SU1710998A1 - Method of measuring deformation of flexible transmission - Google Patents

Abstract

The invention relates to a technique for measuring deformations on moving objects and can be used to study the operating conditions of flexible elements of belt drives. The purpose of the invention is to expand the field of application of the method in the direction of higher frequencies measured, deformations. In the method, a label is applied with a shag-oh-eahaaa va s, and a volume less than half the wavelength of the longitudinal oscillations in the flexible connection, along the entire length of this connection, so that the selected step value ensures the constancy of the distance between each two tags on a flexible link. The sensors are set at a distance equal to the difference between the step size and the maximum value of the measured deformation. When a flexible link is moving, the time intervals between the response of the second sensor from the preceding mark and the first sensor from the subsequent tag are measured, as well as between the responses of the first and second sensors from the same mark. The ratio of these two quantities is multiplied by the distance between the sensors and the distance between the marks is calculated from it to get the value of the absolute current strain. By further processing of the measurement results, the static and dynamic components of the deformation are distinguished. 1 il. - cl

Description

The invention relates to the field of measurement technology, in particular to the field of strain measurement using electrical means.

There is a known method for measuring deformations of a flexible transmission connection, which consists in measuring the distances between fixed-points of a flexible connection.

There is also known a method for measuring the deformation of a flexible communication transmission, which consists in securing the displaced one relative to the other label on the flexible communication, placing two sensors of the passage of the tags near the movement trajectories of the flexible communication, measuring the time intervals of the passage of the labels between the sensors.

The closest to the present invention is a method for measuring the deformation of a flexible transmission link, which means that two marks are placed on a flexible link with a given step, and two distance markers are placed at a given distance of the flexible link trajectory, the time between the characteristic points of the signals of both sensors, one of which is equal to the time interval between operations

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the second sensor from the previous label and the first sensor from the subsequent label and from these data determine the deformation of the flexible connection ..

The disadvantage of this method is the impossibility of measuring the deformations in the region of higher frequencies of the measured deformations.

The aim of the invention is to expand the field of application of the method in the direction of higher frequencies of the measured deformations.

The goal is achieved by the fact that according to a known method of measuring the deformation of a flexible transmission link, which consists in marking marks on a flexible link with a given step, and at a given distance of the flexible link moving, two mark passing sensors are measured, The time intervals between the characteristic points of the signals of both sensors, one of which is equal to the time interval between the responses of the second sensor from the preceding label and the first sensor from the subsequent label, and from these data the deformation of the flexible connection is taken, the second measured interval is taken to be equal to the time interval between the first and second sensors operating from the same mark, the distance between the marks is chosen to be less than half the wavelength of longitudinal vibrations in the flexible connection when measuring the deformations of the highest measured frequency , labels with such a pitch are applied along the entire length of the flexible connection so that the selected pitch value ensures the constancy of the distance between each two labels on the flexible connection, and the distance between the sensors is set equal difference between the step size and the maximum value of the measured strain.

The drawing shows the block diagram of the device that implements the proposed method.

A device that implements the proposed method contains placed at a predetermined distance B in the vicinity of the path of movement of the flexible link 1, on which tags 2 are applied with a given step T, for example light-reflecting, pulse sensors 3 and 4, for example optical, formers 5 and 6 pulses, gauges 7 and 8 time intervals with the Start and Stop inputs, computing devices 9-11, Sensors are connected to the inputs of the meters 7 and 8 time intervals through the drivers 5 and in the pulses, moreover, so that the first sensor 3 is connected to the start of the indicator time 7 and

simultaneously with the input Stop indicator 8 time. The second in the course of the Movement belt sensor 4 is connected to the input of the Stop indicator 7 time and simultaneously with the input

Start indicator 8 time. The outputs of the time interval meters are connected to the computing device. In this case, the step between the marks is chosen to be less than half the wavelength of the longitudinal oscillations in the flexible coupling when measuring the deformations of the highest measured frequency. To do this, calculate the step estimate in millimeters using the formula T1-V / F,

5 where V is the speed of movement of the flexible link, mm / s;

F is the maximum frequency of the measured longitudinal vibrations of the flexible coupling, 1 / s. Next, determine the approximate number of tags

At L / T1, where L is the length of the flexible connection, mm.

The number of marks N and the step T (millimeters) are determined by the formulas

5N-IN l + l:

T L / N. where Nl is the integral part of the number N.

Tags with such a pitch are applied along the entire length of the flexible connection so that the selected

0, the pitch value provided a constant distance between every two marks on the flexible link. The distance B between the two sensors is set equal to the difference between the step size T and the maximum

5, the magnitude of the measured deformation X. Formulas of the invention. A method for measuring the deformation of a flexible transmission connection, which consists in applying a flexible connection with a given step.

0 marks, and in the vicinity of the path of movement of the flexible coupling, two mark passage sensors are placed at a given distance, the time intervals between the characteristic points of the signals of both sensors are measured,

5 one of which is equal to the time interval between the operation of the second sensor from the preceding label and the first sensor from the subsequent label, and from these data the deformation of the flexible one is determined.

0 due to the fact that, in order to expand the field of application of the method towards higher frequencies of the measured deformations, the second measured interval is equal to the time interval

5 between the actions of the first and second sensors from the same mark, the step between the marks is chosen to be less than half the wavelength of the longitudinal oscillations in the flexible connection when measuring deformations of the highest measured frequency, the marks with

in such a step, is applied along the entire length of the flexible link so that the selected step value ensures a constant distance between every two marks on the flexible link.

and the distance between the sensors is set equal to the difference between the step size and the maximum value of the measured strain.

Yu

12

7

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Claims (1)

Claim A method for measuring the deformation of a flexible communication connection of a transmission, which consists in applying 40 marks to a flexible connection with a given step, and placing two mark sensors at a predetermined distance near the path of the flexible connection, measuring the time intervals between the characteristic signal points of both sensors, 45 of which is equal to the time interval between the responses of the second sensor from the previous label and the first sensor from the subsequent label, and according to these data determine the deformation of the flexible connection 50, characterized in that, in order to expand the scope of the method to higher frequencies of the measured strains, the second measured interval is taken equal to the time interval 55 between the responses of the first and second sensors from the same mark, the pitch between the marks is chosen less than half the wavelength of longitudinal vibrations in flexible communication when measuring strains of the highest measured frequency, labels with such a pitch are applied along the entire length of the flexible connection so that the selected step value ensures a constant distance between sensors is set equal to the difference between the value and the maximum value step measured de-