SU756277A1 - Elestoviscosimeter - Google Patents

Description

The invention relates to the field of research of physical and mechanical properties of substances, namely, to information-measuring converters and is intended to determine the viscoelastic characteristics of materials of both organic and non-organic origin.

A device is known with which the viscoelastic properties of substances are judged by the change in the voltage applied to the source of strain when the oscillation amplitude of the rod with the probe is varied and then compensated for this change so that the amplitude of the oscillations remains constant. This device allows you to receive information about the complex module, the substance, as well as to study the processes of its change over time [ί]. .

The selection of the viscous and elastic components of the complex module by this device requires secondary processing of the results, which significantly reduces the accuracy of measurements of viscosity and elastic modulus.

A device for measuring the dynamic modulus of elasticity v2 is known.

substances containing a housing, a cuvette for the test substance, a rod with a probe immersed in the test substance, a drive for moving the rod, a converter for moving it, and a converter for the force developed by the test substance elastic modulus _{) the} output of which is connected to the input of the inverse transducer modulus of elasticity [2].

The use of a parametric compensator, implemented as an inverse transducer of the elastic modulus, makes it possible to ensure high accuracy of measurements of the elastic component of a complex module, however, it does not completely eliminate the influence of its viscous component on the accuracy of the measurement of the elastic modulus, for example, during the synthesis of substances. , most production processes require obtaining information on the qualitative and quantitative characteristics of both viscosity and modulus of elasticity. their effective measurement in the course of process756277

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: sa opens up the possibility of automating measurements, solving problems of stabilization of physicomechanical properties

the final product.

The closest to the proposed technical essence is a device comprising a housing, cuvette ³ for the test substance to the probe rod is dipped in the test substance .For rod displacement sensor displacement sensor rod and force developed investigated.

blown substance, rod speed meter, modulators of elasticity and viscosity moduli, executive units of the modulus of elasticity and viscosity, 15 compensating device, made in the form of an inverse transducer of the modulus of elasticity, containing a stator in the form of a magnetic circuit with a permanent magnet fixed on the 20th case and an anchor with a coil mounted on the rod and a reverse viscosity converter containing a stator with a coil mounted on the housing and an anchor with a coil 25 mounted on the rod, with the input to The armature of the armature of the inverter elastic modulus converter is connected to the output of the executive unit of the elastic modulus channel, the input of which is connected to the output of the elastic modulus signal generator by its inputs connected to the outputs of the amplifier sensor and the rod displacement sensor, and the input of the stator coil of the inverse viscosity converter ^ 5

the viscosity channel unit, whose input is connected to the output of the viscosity shaper, its inputs associated with the outputs of the rod speed meter and amplifier sensor 40, and the armature coil of the inverse viscosity converter is connected to another rod speed meter [s] output.

In the known device is the separation of the reaction of the test substance., Due to its complex module, with periodic deformation into two components - active and reactive e subsequent automatic compensation using a compensating device, made in the form of two inverse transducers. Reverse converters simultaneously and separately create. force summed on the rod 55 of the device. The force applied to the rod from the armature side of the inverse transducer modulus of elasticity is proportional to the product of displacement by the current in the armature coils, the value of which is proportional to the modulus of elasticity, and the force applied to the rod from the armature side of the inverse viscosity converter is proportional to the product of speed

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the movement of the rod on the current in the stator coil, the value of which is proportional to the viscosity.

The sum of the efforts created by the inverse transducers will be equal to the resistance force of the probe during deformation due to the complex modulus of the substance, and its sign will be the opposite sign of the resistance force at each time point.

The constructive dimensions of the inverse transducers are determined by the maximum value of the complex modulus of a given class of substances under study in the required frequency range and are chosen in such a way that their maximum possible efforts are equal. In the course of the measurements it may turn out that mo. The elastic modulus of the material under study is small in size, and dynamic viscosity has a wide range of variation within the maximum possible complex modulus, or vice versa — the material under study has a low viscosity and a wide range of variation of the elastic modulus while also maintaining the maximum value of the complex modulus. In the first case, the inverse transducer modulus of elasticity is underloaded. And the inverse viscosity transducer does not provide the required range of viscosity measurements. In the second case, the underused inverted viscosity converter, and the inverse converter of the elastic modulus does not provide the required measurement range of the dynamic elastic modulus of the test substance.

with. Thus, the known device provides high accuracy of measurement of the modulus of elasticity and viscosity in a certain frequency range, but is complex in a constructive respect, as it requires the installation of two reverse transducers and does not provide the maximum possible range of measurement of the complex module of the test substance.

The purpose of the invention is to simplify the design and expand the range of measurement of the modulus of elasticity and viscosity.

This goal is achieved by installing a compensating device in the elastoviscomemeter. The device is designed as an inverse transducer of a complex module containing an armature with a coil and a stator in the form of a permanent magnet and magnetic conductor, a summing unit, a modulus model module, a viscosity model unit, signal amplifiers displacement and force sensors, displacement velocity meter amplifier, registrars of elastic modulus and viscosity, with the armature coil of the inverter of the complex module connected to the output ummiruyuschego unit, the first

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the input of which is connected to the output of the elastic modulus model block, the inputs of which are connected to the first output of the executive unit of the channel of the elastic modulus and to the second output of the displacement sensor amplifier, second input 5

the summing block is connected to the output of the viscosity model block, the inputs of which are connected to the first output of the viscosity canal actuator and the second output of the amplifier for measuring the rod speed, and the second outputs of the executive blocks are connected to the inputs of the elastic modulus and viscosity recorders, respectively.

The drawing shows a diagram of the device.

The device contains a rod 1, at one end of which the probe 2 is fixed, and its other tip is clamped through the auxiliary spring 3, the clip 4 and the cam 5 is connected to the actuator 6 mounted on the housing (not shown).

On the rod 1 fortified curtain 7 force sensor, anchor 8 with a coil 9 '5

reverse transducer complex-. go module, a shutter 10 displacement sensor and anchor. 11 gauge stem speed 1. The cuvette 12, the coil 13 gauge of the displacement speed of rod 1, the displacement sensor body 14, containing the LEDs 15 and the light bulb 16, the stator of the reverse transducer of the complex module containing the magnetic circuit 17 with 35 threads 18, are reinforced on the device case. In the annular gap formed by coaxially made probes 2 and cuvette 12 there is an analyte 19. On the bracket 4 there is a reinforced $$

force sensor housing 20 with photodiodes 21 and light bulbs 22. Photodiodes 21 are connected to the input of an amplifier of a force sensor 23, the first output connected to the first input of a signal generator of a modulus of elasticity 2'4, which is a multiplying device, the second input of which is connected to the output of a displacement sensor amplifier 25 the input associated with the output of the photodiodes 15 displacement sensor, and the output of the signal conditioner modulus of elasticity module 24 is connected to the input of the executive unit 26 of the channel of the modulus of elasticity, the first output of which is connected with the first input of the unit module models 55

elasticity 27, the second input of the second through the second output of the amplifier 25 is connected with the photodiodes 15 of the displacement sensor, and the output of the block of the model of the modulus of elasticity 27 is connected with the first input of the 60 summing block 28.

The output of the coil 13 gauge of the speed of movement of the rod 1 is connected with the input of the amplifier 29, the first output of which is connected with the first input of the for-

worlds viscosity signal 30, which is a multiplying device, the second input of which is connected to the output of the force sensor amplifier 23, and its output is connected to the 5th input of the executive unit 31 of the viscosity channel, the first output of which is connected to the first input of the viscosity model block 32, the second input of which is connected with the second output of force т 0 body 29, and the output of the block 32 of the viscosity model is connected with the second input of the summing block 28, the output of which is connected with the input of the coil 9 of the armature 8 of the inverse transducer of the complex module. The second outputs of executive ’· т blocks 26 and 31 are connected with registrars 33 elastic moduli and 34 viscosities, respectively.

Elastoviscometer works as follows.

20 In the absence of substance 19 in cuvette 12, turning on drive 6 causes oscillations of rod 1, which causes the appearance of periodic signals at the output of photodiodes 21

? 5 force sensors, photodiodes 15 displacement sensors and a coil 13 measuring the speed of movement, the amplitude and phase of which is determined by the amplitude, the frequency of the driving oscillation of the drive

30 6 and the parameters of the mechanical part (mass, self-damping, elastic auxiliary spring). Amplified by amplifiers 23, 25 and 29, these signals are fed to the inputs of the worlds 24 and 30, which are adjusted so that their output signals are zero.

In this case, the signals at the output of the execution units 26 and

^ 0 31. From the second outputs of the amplifiers 25 and 29, these signals arrive at the second inputs of the modules of the modulus of elasticity module 27 and the viscosity model 32, the first inputs of which are respectively connected to the outputs of the executive units of the channels of the elastic modulus 26 and viscosity 31.

The blocks of moduli of elastic modulus 27 and viscosity 32 are multiplying devices, therefore at 50 absence of substance 19 in cuvette 12 the signals from their outputs are zero. Consequently, the signal at the output of the total block 28 connected to the input of the coil 9 of the armature 8 55 of the inverter of the complex module will also be zero.

In the presence of substance 19 in the cell 12, resistance to the movement of the probe 2 arises, which is due to its 60 complex module. This causes a change in the amplitude and phases of oscillations of the rod 1 and, consequently, the amplitude and phases of the output signals of the photodiodes 15, 21 and coil 13. In the former 55 of the modulus of elastic modulus 24, where

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multiplication of the signal proportional to the full resistance force and a signal proportional to the movement of the rod 1 occurs, a signal is generated that is proportional to the active component of the complex module, that is, the elastic modulus, which will cause current to appear at the output of the execution unit 26, which is modulated by the movement signal of the rod 1 from the amplifier 25 output in the modulus model of the elastic modulus 27. The output signal of the modulus modulus modulus block 27 models the active component of the resistance to movement of the probe 2, which through the first th input enters the summing unit 28.

In the viscosity signal generator 30, where the signal multiplies proportional to the full resistance force and the signal proportional to the speed of movement of the rod 1, multiplies the signal proportional to the reactive component of the complex module, i.e. the viscosity of the substance that causes the appearance of current at the output of the actuator 31, which is modulated by the signal of the speed of movement of the rod 1 from the output of the amplifier 29 from the block. 32 viscosity models. The output signal of the block 32 of the viscosity model models the reactive component of the resistance to movement of the probe 2, which through the second entrance enters the summing block 28.

The output signal of the summing unit 28, proportional to the complex module of the material under study, falls into the coil 9 of the armature 8 of the inverse transducer of the complex module, where an electromagnetic force occurs, whose zelichina is equal to the resistance force of the probe 2 in substance 19, due to its complex module, and its sign is inverse sign of resistance force. The signals from the outputs of the formers 24 and 30 are zero, which indicates full compensation of the viscoelastic forces of resistance to the probe 2, and the signals from the outputs of the execution units 2 6 and 31 'are proportional to the elastic modulus and viscosity modulus, respectively, and are recorded in the recorders 33 and 34 .

A change in the elastic modulus or viscosity of a substance leads to a deviation of the signal at the output of drivers 24 or 31 and a corresponding change in the output of the blocks of the model of modulus of elasticity 27 or viscosity 32, which causes a corresponding change in the output signal of the summing block 28 and the current in the coil 9 of the armature 8 of the inverter complex module to such a magnitude and in this direction

so that the force due to the complex modulus of a substance would be compensated by the electromagnetic force of the inverse transducer. ’

Thus, the algebraic sum of the forces acting on the stem from the substance under study and the inverse transducer of the complex module is always zero, which indicates the constancy of the frequency characteristics of the electromechanical system. This allows you to change over a wide range the frequency of deformation of a substance using the actuator 6.

Using the model of elastic modulus 27 and the model of viscosity 32, the output signals of which are proportional to the elastic and viscous forces of the test substance, ”summing in the summing unit, makes it possible to more fully use the power characteristics of the compensating device made in the form of an inverse transducer of the complex module and expand the metrological capabilities of the proposed elastoviscometer as a measuring converter of the modulus of elasticity and viscosity of substances.

Claims (1)

Claim Elastoviscoeimeter, comprising a housing, a cuvette for a test substance, a rod with a probe immersed in the test substance, a rod movement drive, a rod movement sensor, a force developed by the test substance, a rod movement meter, viscosity modulus and elastic modulus, channel execution units viscosity and modulus of elasticity and a compensating device, and the inputs of the execution units are connected to the outputs of the corresponding drivers, characterized in that, in order to extend the range it has measurements, it additionally includes a summing unit, a viscosity model unit, a elasticity modeling unit, amplifiers for measuring the speed of moving the rod, sensors for moving the rod and the force, and the compensating device is designed as an inverse transducer containing a stator in the form of a magnetic conductor and a permanent magnet, mounted on the housing, and anchored on the rod anchor with a coil while the outputs of the measuring speed of movement of the rod and the displacement sensor through amplifiers are connected respectively to the first input viscosity rows of blocks and modules of elasticity modulus and the first input of viscosity and modulus signals, the second input of which via an amplifier connected to the output of the force sensor, ten the second inputs of the viscosity and elastic modulus blocks are connected to the first outputs of the executive blocks of the respective channels, the second outputs of which are connected to the inputs of the viscosity and elastic moduli registers, respectively, and the outputs of the viscosity and elastic modulus blocks are connected through the summing block oat fir tree.