RU2184929C2 - Device measuring linear displacement and deformation of object - Google Patents

Abstract

FIELD: measuring technology, measurement of displacement and deformation of object as result of thermal shocks, elastic collisions and other disturbing effects. SUBSTANCE: device has three identical distance sensors connected correspondingly to instrument converters. First two sensors are placed differentially with reference to surface of tested object and third sensor is positioned with standard displacement relative to second sensor, in parallel to its sensitivity axis. Device incorporates information processing unit which includes one adder, three subtracters, three dividers, two multipliers and storage. EFFECT: expanded functional capabilities, increased measurement accuracy and simplified design of device. 1 dwg

Description

 The invention relates to measuring technique and can be used to measure the displacements and deformations of objects as a result of thermal, elastic and other disturbing influences.

 There are many measuring devices that implement an algorithmic method for measuring the displacements of objects subject to thermal and elastic deformations. For example, a device by a.s. 1562674, cl. G 01 B 7/00, where as a result of using three measuring channels, the value of the radial movement of the shaft is obtained with simultaneous compensation of disturbing influences from the side of the controlled object. Their disadvantage is the lack of information due to the lack of control of the linear deformation of the object during the measurement process.

 A device according to a is also known. from. 1663396, class G 01 B 7/00, where the use of the same measuring channels as in the first analogue, with some complication of the information processing unit, allows you to additionally obtain the linear strain of the object.

где k - чувствительность измерительных каналов;
х₀ - начальное расстояние от 1-го и 2-го датчиков до контролируемого объекта, установленных дифференциально;
x_t- образцовое смещение третьего датчика относительно второго, известное с высокой степенью точности;
x₁ - компонента, характеризующая линейное перемещение точки контролируемого объекта, принятой за полюс (в данном случае принят центр объекта);
x₂ - компонента, характеризующая линейную деформацию объекта между его крайними точками.Closest to the technical nature of the present invention is a technical solution published in "Measuring equipment", 1992, 5, p. 17-18, containing three identical distance sensors with hyperbolic transformation functions, two of which are installed differentially with respect to the controlled object, and the third - with an exemplary offset relative to the second parallel to its sensitivity axis, three corresponding measuring transducers, an addition unit, three subtraction blocks, two multiplication blocks, three blocks divisions and a memory block, the output signals of the measuring channels are approximated by a system of equations

where k is the sensitivity of the measuring channels;
x ₀ - the initial distance from the 1st and 2nd sensors to the controlled object, set differentially;
x _t is the model displacement of the third sensor relative to the second, known with a high degree of accuracy;
x ₁ is the component characterizing the linear displacement of the point of the controlled object adopted as a pole (in this case, the center of the object is adopted);
x ₂ - component that characterizes the linear deformation of the object between its extreme points.

Как видно из выражений, входящих в систему (1),

это половинная деформация части объекта от точки О, принятой за полюс и расположенной в данном случае в центре контролируемого объекта, до соответствующих сторон объекта. Значение х₂/2 в всех выражениях системы (1) совпадает, если соблюдено условие симметрии деформации в одну и другую сторону от полюса О. Последнее не всегда возможно.Accordingly, at the output of the processing unit we obtain signals characterizing the named components and insensitive to disturbing influences from the side of the controlled object

As can be seen from the expressions included in system (1),

this is a half deformation of a part of the object from point O, taken as a pole and located in this case in the center of the controlled object, to the corresponding sides of the object. The value of x _2/2 in all expressions of system (1) coincides if the condition of symmetry of deformation to one and the other side from the pole O is met. The latter is not always possible.

 The disadvantages of the known device include insufficient measurement accuracy due to the influence on the result of uneven deformation along the length of the controlled object, which also leads to a limitation of the functionality of the device.

 The essence of the invention lies in the fact that in a device for measuring linear displacements and deformations of an object, containing three identical distance sensors with hyperbolic transformation functions, two of which are set differentially with respect to the controlled object, and the third with an exemplary displacement relative to the second, parallel to its sensitivity axis, connected to the corresponding measuring transducers, an addition block, three subtraction blocks, two multiplication blocks, three division blocks and a memory block, the output of the first measuring transducer of the first sensor is connected to the first input of the addition unit and the first input of the first division unit, the output of the second measuring transducer of the second sensor is connected to the second input of the adding unit and the direct input of the first subtraction unit, the output of the third measuring transducer of the third sensor is connected to the inverse input of the first block subtraction and the second input of the first division block, the outputs of the addition block and the first subtraction block are connected to the corresponding inputs of the second block division window, the output of which, as well as the output of the first division block and the first output of the memory block are connected to the corresponding inputs of the first multiplication block, the output of the first multiplication block is connected to the inverse input of the second subtraction block, the second output of the memory block is connected to its direct input, and the output of the second the subtraction block is the first output of the device, the outputs of the second measuring transducer and the first subtraction block are connected to the corresponding inputs of the third division block, the output of the third division block is connected to one of the inputs of the second multiplication block, to the other two inputs of which the output of the first division block and the first output of the memory block are connected, the output of the second multiplication block is connected to the direct input of the third subtraction block, the third output of the memory block is connected to its inverse input, and the output of the third block subtraction serves as the second output of the device. In this case, the displacement of a point located on one of the faces of the controlled object is taken as the informative value characterizing the movement of the object, and the strain value characterizes the integral deformation of the object between its extreme faces, consisting of individual deformations of parts of the object, varying differently depending on changes in the causes of deformation.

 As a result, the functionality of the device is expanded and, in a certain case, the measurement accuracy is increased.

 The drawing shows a block diagram of a device for measuring linear displacements and deformations of an object.

The device contains three identical distance sensors 1-3, connected, respectively, to the measuring transducers 4, 5 and 6. The first two sensors 1 and 2 are installed relative to the controlled object differentially with a known initial distance x ₀ from its surface, and the third sensor 3 with exemplary displacement x _t relative to the second, parallel to its sensitivity axis. The device has an information processing unit, which contains one addition block 7, three subtraction blocks 8, 9 and 10, three division blocks 11-13, two multiplication blocks 14 and 15 and a memory block 16. Moreover, the output of the first measuring transducer 4 of the first sensor 1 is connected to the first input of the addition unit 7 and the first input of the first division unit 11, the output of the second measuring transducer is connected to the second input of the addition unit 7, the direct input of the first subtraction unit 8 and the first input of the third division unit 12 5 of the second sensor 2, the output of the third measuring transducer 6 of the third sensor 3 is connected to the inverse input of the first subtraction unit 8 and the second input of the first division unit 11, the outputs of the addition unit 7 and the first block subtraction windows 8 are connected to the corresponding inputs of the second division block 13, in addition, the output of the first subtraction block 8 is connected to the second input of the third division block 12, the outputs of the first and second division blocks 11 and 13, as well as the first output of the memory block 16 are connected to the corresponding inputs the first block 15 of the multiplication, the output of which is connected to the inverse input of the second block 10 of the subtraction, the direct input of which is connected to the second output of the block 16 of the memory, and the output of the second block 10 of the subtraction is the first output of the device, the output of the third division lock 12 is connected to one of the inputs of the second multiplication unit 14, the output of the first division unit 11 and the first output of the memory unit 16 are connected respectively to the other two inputs, the output of the second multiplication unit 14 is connected to the direct input of the third subtraction unit 9, to the inverse input of which the third output of the memory unit 16 is connected, and the output of the third subtraction unit 9 serves as the second output of the device.

 The device operates as follows.

где k - чувствительность измерительных каналов, зависящая от внешних возмущений;
х₀ - начальное расстояние от 1-го и 2-го датчиков до поверхности контролируемого объекта и постоянное расстояние от третьего датчика до поверхности контролируемого объекта;
x_t - образцовое смещение третьего датчика относительно второго в направлении их осей чувствительности;
x₁ - компонента, характеризующая линейное перемещение контролируемого объекта по точке О, расположенной на одной из граней объекта;
x₂ - компонента, характеризующая интегральную деформацию контролируемого объекта между его противолежащими гранями.When moving and deforming the controlled object in the directions shown in the figure by arrows, the outputs of the transducers 4-6 receive signals

where k is the sensitivity of the measuring channels, depending on external disturbances;
x ₀ - the initial distance from the 1st and 2nd sensors to the surface of the controlled object and a constant distance from the third sensor to the surface of the controlled object;
x _t is the model displacement of the third sensor relative to the second in the direction of their sensitivity axes;
x ₁ - component characterizing the linear movement of the controlled object at point O, located on one of the faces of the object
x ₂ is the component characterizing the integral deformation of the controlled object between its opposite faces.

Сигналы (5) и (6) с выходов второго 5 и третьего 6 измерительных преобразователей поступают на входы первого блока 8 вычитания, на выходе которого получают сигнал

Сигналы (4) и (6) с выходов первого 4 и третьего 6 измерительных преобразователей поступают на входы первого блока 11 деления, на выходе которого получают сигнал

Сигнал (5) с выхода второго измерительного преобразователя 5 и сигнал (8) с выхода первого блока 8 вычитания поступают на входы блока 12 деления, на выходе которого получаем

Сигналы (9) и (10) с блоков 11 и 12 деления, а также сигнал x₁ с первого выхода блока 16 памяти поступают на входы блока 14 умножения, на выходе которого получают сигнал

Сигнал (11) с выхода блока 14, а также сигнал х₀ с соответствующего выхода блока 16 памяти поступают на соответствующие входы блока 9 вычитания, на выходе которого, являющегося одним из выходов устройства, получают сигнал

характеризующий линейное перемещение контролируемого объекта по точке О, расположенной на одной из граней объекта.The signals (4) and (5) from the outputs of the first 4 and second 5 measuring transducers are fed to the inputs of the addition unit 7, the output of which receives a signal

The signals (5) and (6) from the outputs of the second 5 and third 6 measuring transducers are fed to the inputs of the first subtraction unit 8, the output of which receives a signal

Signals (4) and (6) from the outputs of the first 4 and third 6 measuring transducers are fed to the inputs of the first division unit 11, the output of which receives a signal

The signal (5) from the output of the second measuring transducer 5 and the signal (8) from the output of the first subtraction unit 8 are fed to the inputs of the division unit 12, at the output of which we obtain

The signals (9) and (10) from the blocks 11 and 12 of the division, as well as the signal x ₁ from the first output of the memory block 16 are fed to the inputs of the multiplication block 14, the output of which receives a signal

The signal (11) from the output of block 14, as well as the signal x ₀ from the corresponding output of block 16 of the memory, is supplied to the corresponding inputs of the subtraction block 9, the output of which, which is one of the outputs of the device, receives a signal

characterizing the linear movement of the controlled object at point O, located on one of the faces of the object.

Сигналы (9) и (13) с блоков 11 и 13 деления, а также сигнал х_t с первого выхода блока 16 памяти поступают на входы блока 15 умножения, на выходе которого получают сигнал

Сигнал (14) с выхода блока 14 умножения, а также сигнал 2x₀ с соответствующего выхода блока 16 памяти поступают на соответствующие входы блока 10 вычитания, на выходе которого, являющимся вторым выходом устройства, получают сигнал

характеризующий интегральную деформацию контролируемого объекта между его противолежащими гранями.The signal (7) from the output of the addition unit 7 and the signal (8) from the output of the first subtraction unit 8 are supplied to the corresponding inputs of the division unit 13, at the output of which we obtain

The signals (9) and (13) from the blocks 11 and 13 of the division, as well as the signal x _t from the first output of the memory block 16 are fed to the inputs of the multiplication block 15, the output of which receives a signal

The signal (14) from the output of the multiplication unit 14, as well as the 2x ₀ signal from the corresponding output of the memory unit 16, are supplied to the corresponding inputs of the subtraction unit 10, the output of which, which is the second output of the device, receives a signal

characterizing the integral deformation of the controlled object between its opposite faces.

 The use of this invention extends the functionality of its use due to the possibility of measuring unevenly deformed objects and increases in this case the accuracy of the measurement.

Claims (1)

 A device for measuring linear displacements and deformations of an object, containing three identical distance sensors with hyperbolic transformation functions, two of which are installed differentially with respect to the controlled object, and the third with an exemplary displacement relative to the second, parallel to its sensitivity axis, connected to the corresponding transducers, and a unit information processing, including the addition block, three subtraction blocks, two multiplication blocks, three division blocks and a memory block, m the output of the first measuring transducer of the first sensor is connected to the first input of the addition unit and the first input of the first division unit, the output of the second measuring transducer of the second sensor is connected to the second input of the adding unit and the direct input of the first subtraction unit, the output of the third measuring transducer of the third sensor is connected to the inverse input of the first the subtraction unit and the second input of the first division unit, the outputs of the addition unit and the first subtraction unit are connected to the corresponding inputs of the second a division lock, the output of which, as well as the output of the first division block and the first output of the memory block are connected to the corresponding inputs of the first multiplication block, the output of the first multiplication block is connected to the inverse input of the second subtraction block, the second output of the memory block is connected to its direct input, and the output of the second the subtraction block is the first output of the device, characterized in that the outputs of the second measuring transducer and the first subtraction block are connected to the corresponding inputs of the third division block, the output of the third the division window is connected to one of the inputs of the second multiplication unit, the output of the first division unit and the first output of the memory unit are connected respectively to the two other inputs of the output, the output of the second multiplication unit is connected to the direct input of the third subtraction unit, the third output of the memory unit is connected to its inverse input, and the output of the third subtraction block serves as the second output of the device.