RU2135980C1 - Device measuring viscosity - Google Patents

Abstract

FIELD: measurement technology. SUBSTANCE: invention is intended to test structurized liquids in research laboratories, in medicine and industry. Device includes vibration transmitter with probing body-sonde submerged in cell, instrument self-excited oscillator and power self-excited oscillator. Device is also fitted with simulator of transmitter and unit of switch of conditions. Unit of switch of conditions has capability for synchronous connection in turn to instrument self-excited oscillator of simulator or transmitter and at same time to self-excited oscillator of transmitter or simulator. EFFECT: enlarged body of information, determination of viscosity of broken and formed structure. 2 dwg

Description

 The invention relates to techniques for measuring viscosity, and more particularly to a device for viscometers for monitoring structured liquids in research laboratories, in medicine, in industry.

 Many process liquids under static conditions show a distinct tendency to form a structure. Moreover, the binding energy of particles is such that the intensities of mechanical action encountered in practice are sufficient for its destruction. The source of this effect can be technological devices such as mixers, pumps. To characterize such fluids, a single viscosity value that can be measured by any method is not enough.

 Usually use rotational viscometers. The dependence of stress on shear rate is experimentally obtained. The viscosity of the formed structure is determined from the slope of the dependence at low velocity values. The viscosity of the fractured structure is defined as the slope of the dependence at high speeds. Measurements performed at a single shear rate give the value of the effective viscosity associated with an indefinite degree of fracture.

 From the point of view of the characteristics of the structure, the use of vibrational methods is more correct, because rotational viscometers assume a steady flow regime (long shift) and they themselves "provoke" the formation of an anisotropic structure along the flow, the formation of chain aggregates.

 The use of Newtonian vibratory viscometers to control structured fluids gives effective viscosity. Usually small amplitudes of low-frequency oscillations are used, which have a less destructive effect than long-term shear at a constant speed.

 Known vibrational viscometers (BB), for example BBM-3M [Belyakov V.L. Automation of oil and water field preparation. -M .: Nedra, 1988, 232 S.].

 Closest to the proposed technical essence is a tuning fork viscometer [Gochen Zhu, Lao Tzu Xu. Measurement of viscosity and density using an oscillating ball // Instruments for scientific research. 1985, N 8, p. 144 - 147], the sensor of which is included in the feedback circuit of the generator supporting the resonance frequency.

 Such devices cannot determine the viscosity of a destroyed and formed structure.

 The objective of the invention is to increase the amount obtained by measuring information.

 The technical result is achieved in that the viscometer comprising a measuring generator, a vibration sensor and a recording device further comprises a high voltage power generator, a mode switching unit (BPR) and a sensor simulator.

 Description of the device (Fig. 1).

 The main structural element is a vibration sensor (1) with an attached test body (7). In the measurement mode U, the sensor (1) is connected to the measuring generator (4) and provides harmonic oscillations of the test body with a small amplitude. There is friction of the test body on the liquid. In this case, the output voltage U, which is proportional to the mechanical resistance and related to the viscosity, is fixed using a recorder (5). In the fracture mode P, the sensor (1) is connected to a high-voltage generator (6) and provides an oscillatory motion of a test body with a large amplitude that can destroy the structure of the surrounding fluid. In neutral state H, the sensor (1) and the simulator (3) are not connected to any of the generators. The measuring generator (4) and the high-voltage generator (6) are self-oscillators, in the feedback circuit of which, in the corresponding mode, either a sensor (1) or a simulator (3) is connected. They (sensors) have similar electrical parameters and when replacing one with another, the generators continue to operate in the same frequency and amplitude range. That is, when switching, no additional time is required for the measuring generator to enter the mode. This allows you to start registration immediately after switching. Switching is carried out using the mode switching unit (BPR) (2).

The measurements are carried out as follows. Using the block switching modes (BPR) (2) include a sensor (1) in the feedback circuit of the measuring generator (4). Determine (mark on the field of the recorder (5)) the output voltage U _in when the test body (7) is in the air. A calibration fluid (QL) is placed in the cell (8). A test body is immersed in the QOL (7). The output voltage U _{k is} determined (noted on the field of the recorder (5)) when the test body is in the QOL. A controlled fluid is placed in the cell (8). A test body (7) is immersed in the liquid and using BPR (2) they include a sensor (1) in the feedback circuit of the high-voltage generator (6), and a simulator (3) in the feedback circuit of the measuring generator (4). They withstand the failure mode P for a predetermined time (in the given example, 2 minutes).

Using the BPR unit, the measurement mode (I) is turned on - the sensor (1) is connected to the measuring generator (4) and the recorder (5) is started. In this case, sequential values U _{i of the} output voltage U corresponding to the process of restoring the structure destroyed in the P mode are recorded on the recorder field. That is, a graph of the dependence of the output voltage U on time is obtained, having marked voltage levels corresponding to the oscillations of the probe in the air (U _in ) and in the calibration fluid (U _to ).

(расшифровку символов см. ниже).For Newtonian fluids, the friction between an oscillating test body and a fluid is described by the formula

(decoding of characters see below).

In reality, in addition to the liquid resistance, there is a mechanical resistance of the sensor and the total observed mechanical resistance Z = Z _w + Z _c .

U = E • Z.During measurement, the device maintains a constant amplitude of oscillations, and the output voltage U is proportional to the exciting force and, accordingly, to the total effective resistance

U = E • Z.

Character decoding:
Z is the total effective mechanical resistance;
F is the force that stimulates the movement;
ξ is the amplitude of motion, constant during measurements;
ξ ′ is the amplitude of the speed of movement, constant during measurements;
U _F is the voltage proportional to the force F is the exciting voltage;
ρ is the fluid density;
η is the viscosity of the liquid;
U _ξ is the voltage proportional to the amplitude of the oscillations, constant during measurements;
U - output signal - the current value of the output voltage, proportional to Z, F and U _F.

 The subscript “c” indicates a measurement when the test body moves in air.

напряжение, пропорциональное возбуждающей силе при положении зонда в воздухе;
U_в - выходной сигнал при положении зонда в воздухе.

voltage proportional to the exciting force when the probe is in the air;
U _in - the output signal when the probe is in the air.

 The subscript “k” indicates a measurement as the test body moves in the calibration fluid.

напряжение, пропорциональное возбуждающей силе при положении зонда в калибровочной жидкости (КЖ);
U_к - выходной сигнал при положении зонда в КЖ.

voltage proportional to the exciting force when the probe is in the calibration fluid (QL);
U _to - the output signal when the position of the probe in the QOL.

 The lower index "g" indicates the measurement during the movement of the test body in the test fluid.

напряжение пропорциональное возбуждающей силе при положении зонда в исследуемой жидкости (Ж);
U_ж - выходной сигнал при положении зонда в исследуемой жидкости;
U_i - выходной сигнал U_ж в избранной точке на графике зависимости напряжения от времени t, соответствует моменту времени t_i;
ΔU = U - U_в = E(Z - Z_в);
ΔU_i = U_i - U_в = E•Z_i;
ΔU_к = U_к - U_в = E•Z_к;
ΔU_ж = U_ж - U_в = E•Z_ж;

Z_ж - механическое сопротивление исследуемой жидкости;
ρ_ж - плотность исследуемой жидкости;
η_ж - вязкость исследуемой жидкости;

Z_к - механическое сопротивление калибровочной жидкости;
ρ_к - плотность калибровочной жидкости;
η_к - вязкость калибровочной жидкости;
A, B, C, D, E, K - коэффициенты пропорциональности;

Z_отн - относительное механическое сопротивление, используется для сравнения реологических (вязких) свойств жидкостей со стандартом (КЖ).

voltage proportional to the exciting force when the probe is in the test fluid (G);
U _W - output signal when the probe is in the test fluid;
U _i - the output signal U _W at a selected point on the graph of voltage versus time t, corresponds to time t _i ;
ΔU = U - U _in = E (Z - Z _in );
ΔU _i = U _i - U _in = E • Z _i ;
ΔU _к = U _к - U _в = E • Z _к ;
ΔU _g = U _g - U _in = E • Z _w;

Z _W - mechanical resistance of the investigated fluid;
ρ _W - density of the investigated fluid;
η _W - viscosity of the investigated fluid;

Z _to - mechanical resistance of the calibration fluid;
ρ _to - the density of the calibration fluid;
η _to - viscosity of the calibration fluid;
A, B, C, D, E, K - proportionality coefficients;

Z _rel - relative mechanical resistance, is used to compare the rheological (viscous) properties of liquids with the standard (QL).

Определяют относительное механическое сопротивление сформировавшейся структуры

2. После окончания регистрации зависимость U-t превращают в зависимость

или, что то же Z_отн-t, вычитая U_в от уровней U_i зафиксированных точек и находя соответствующие отношения разностей напряжений

Z_max и Z₀ находят непосредственно по графику или используя аппроксимирующее уравнение.After obtaining the dependence of U on t, two sequences of actions are possible:
1. After the registration is completed, the obtained dependence Ut is extrapolated to the zero initial moment of time and U _{0 is} determined. Then find the asymptotic value of U _max , which tends to U with increasing observation time. The relative mechanical resistance of the fractured structure is determined

The relative mechanical resistance of the formed structure is determined

2. After the completion of the registration, the dependence Ut is turned into a dependence

or, what is the same Z _rel -t, subtracting U _in from the levels U _{i of} fixed points and finding the corresponding relationship of voltage differences

Z _max and Z _{0 are} found directly on the schedule or using the approximating equation.

Рассчитывают значение вязкости сформированной структуры по формуле

Пример конкретного выполнения. Камертон из стали с частотой резонанса 700 Гц имеет пробное тело - зонд в виде иглы диаметром 1,5 мм. Зонд погружен в ячейку диаметром 10 мм, емкостью 1 см³. Имитатор - такой же камертон без зонда. Измерительный автогенератор собран на микросхемах 140 серии, обеспечивает возбуждающее напряжение на воздухе ≤ 1 В. Автогенератор мощности имеет трансформаторный выход, обеспечивает возбуждающее напряжение на воздухе ≥ 300 В. БПР - многоконтактный переключатель. Регистратор - самописец "Эндим 622.01". Амплитуда колебаний зонда в режиме измерения ≈ 0,01 мм. Амплитуда колебаний зонда в режиме разрушения ≥ 3 мм.The value of the viscosity of the destroyed structure is calculated by the formula

The value of the viscosity of the formed structure is calculated by the formula

An example of a specific implementation. A tuning fork made of steel with a resonance frequency of 700 Hz has a test body - a probe in the form of a needle with a diameter of 1.5 mm. The probe is immersed in a cell with a diameter of 10 mm, a capacity of 1 cm ³ . The simulator is the same tuning fork without a probe. The measuring oscillator is assembled on 140-series microcircuits, it provides exciting voltage in air ≤ 1 V. The power generator has a transformer output, it provides exciting voltage in air ≥ 300 V. BPR is a multi-contact switch. The registrar is a recorder "Endim 622.01". The oscillation amplitude of the probe in the measurement mode is ≈ 0.01 mm. The amplitude of the oscillations of the probe in the destruction mode ≥ 3 mm.

The oil viscosity of the Chkalovskoye field was measured (Fig. 2) at 15 ^° C (curve 1) and 19 ^° C (curve 2). Glycerin was used as a calibration fluid. Sweep recorder 10 s / cm. The diagram was digitized manually and the relative mechanical resistance was found for 16 points (below, the subscript _{rel. Is} not indicated). The values of Z _i , tied to the corresponding time, were entered into an IBM-compatible computer. The dependencies were approximated by the equation
Z = Z ₀ + ΔZ (1-e ^{t / τ} ),
where t is the current time, τ is the relaxation time of the structure, ΔZ = Z _max -Z ₀ is the changing part of the resistance.

The following values are obtained:
Z _{max; 15} = 3.1; Z _{max; 19} = 1.36;
Z is _{0; 15} = 0.79; Z is _{0; 19} = 0.62;
ΔZ ₁₅ = 2.31; ΔZ ₁₉ = 0.74;
τ ₁₅ = 96.5 s; τ ₁₉ = = 95.7 s;
ρ _W ≈ 0.81 g / cm ³ ;
ρ _to ≈ 1.26 g / cm ³ ;
η _to ≈ 1000 MPa • s.

Вязкость сформировавшейся структуры при 15^oC

Вязкость разрушенной структуры при 19^oC

Вязкость сформировавшейся структуры при 19^oC

Таким образом, предлагаемое устройство позволило получить больше информации и дать более полную характеристику объекта, чем было бы возможно при использовании обычных вибрационных вискозиметров.The viscosity of the fractured structure at 15 ^o C

The viscosity of the formed structure at 15 ^o C

The viscosity of the fractured structure at 19 ^o C

The viscosity of the formed structure at 19 ^o C

Thus, the proposed device allowed to obtain more information and give a more complete description of the object than would be possible using conventional vibrational viscometers.

Claims (1)

 A device for measuring viscosity, comprising a vibration sensor with a test probe body, a cell, a measuring oscillator connected to the sensor, and a recorder, characterized in that it further comprises a power oscillator, a sensor simulator and a mode switching unit with the possibility of alternating synchronous connection to the measuring oscillator simulator or sensor and simultaneously to the power generator - sensor or simulator.

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