RU2705655C1 - Method of determining diffusion coefficient in solid articles from orthotropic capillary-porous materials - Google Patents

Abstract

FIELD: measuring equipment.

SUBSTANCE: invention relates to measurement equipment and can be used in investigation of mass transfer processes in capillary-porous materials for determination of diffusion coefficients of solvents in construction materials and structures. Method of determining the diffusion coefficient in solid articles from orthotropic capillary-porous materials involves creating in the analyzed sample a uniform initial content of a solvent distributed in a solid phase, bringing the flat surface of the sample into contact with a solvent dose source, pulse dampening in the specified direction of the analyzed orthotropic material along a straight line with a constant solvent constant flow source, performing electrodes of a galvanic converter in the form of rectilinear sections and their arrangement on both sides of a pulse humidification line on direct parallel lines of pulse moistening and located at the same specified distance from it, measuring time variation of EMF of galvanic converter, wherein measurement of diffusion coefficient is carried out under condition of achievement in experiment of maximum signal of galvanic sensor E_max, which is 0.75–0.95 of maximum possible value of given signal E_e, corresponding to transition of solvent from region associated with solid phase of analyzed material into free state region, fixing time moments τ₁ and τ₂, at which identical values of signals of galvanic sensor E₁ and E₂ are achieved from range (0.7–0.9) E_e respectively, on the ascending and descending branches of the signal variation curve in time, and the diffusion coefficient is calculated by the formula: D=r₀ ²(τ₂-τ₁)/[4τ₂τ₁ln(τ₂/τ₁)], where r₀ is distance between electrodes of galvanic converter and point of action of solvent dose on surface of controlled article.

EFFECT: high accuracy of measuring diffusion coefficient of solvents in solid articles from orthotropic capillary-porous materials.

1 cl, 1 dwg, 1 tbl

Description

The invention relates to measuring technique and can be used in the study of mass transfer processes in capillary-porous materials to determine the diffusion coefficients of solvents in building materials and structures, as well as in the food, chemical and other industries. Orthotropic materials are characterized by a significant difference in properties in perpendicular directions, for example, along and across the fibers.

A known method for determining the diffusion coefficient of solvents in bulk products from capillary-porous materials (RF patent 2492457, IPC ¹¹ G01N 27/26, G01N 13/00, 09/10/2013, Bull. No. 25.). In a massive product made of capillary-porous materials having at least one flat surface (for example, cement or gypsum boards), a uniform initial distribution of solvent is created. Then, a pulsed point contact is made between the flat surface of the test article and the solvent source, then this surface is waterproofed, the electrodes of the galvanic converter are placed on this surface along a concentric circle relative to the solvent dose point, the time-dependent change in the EMF of the galvanic converter is measured, and the sought diffusion coefficient is calculated from the established dependence .

The disadvantages of this method are the low accuracy of determining the diffusion coefficient of solvents in products made of orthotropic materials due to the inadequacy of the mathematical description used for the mass transfer process in a massive product with point-like pulsed action due to a significant difference in material properties in different directions; the inability to determine the diffusion coefficient in different directions of an orthotropic capillary-porous material, for example, wood along and across the fibers.

The closest is a method for determining the coefficient of solvents in bulk products from orthotropic capillary-porous materials (RF patent 2549613, IPC ¹¹ G01N 27/26, G01N 13/00, 04/27/2015, Bull. No. 12). In a massive article made of orthotropic capillary-porous materials having at least one flat surface (for example, cement or gypsum boards), a uniform initial distribution of solvent is created. Then, an impulse action is performed on the flat surface of the test article with a dose of solvent in a straight line in a given direction of the orthotropic material, electrodes of the galvanic converter are made in the form of straight sections and they are placed on both sides of the impulse action line on straight lines parallel to the impulse action line and located at the same given distance from it, determine the point in time corresponding to the maximum emf of the Converter, and calculate the desired coefficient according to the established dependence.

The disadvantage of this method is the low accuracy of determining the moment of reaching the maximum EMF, where the time derivative of the converter signal is close to zero, and there is insufficient sensitivity of the measured parameter to the time change.

The technical problem of the proposed technical solution involves improving the accuracy of measuring the diffusion coefficient of solvents in bulk products from orthotropic capillary-porous materials.

The technical problem is achieved in that in a method for determining the diffusion coefficient of solvents in bulk products from orthotropic capillary-porous materials having at least one flat surface, with a significant difference in material properties in perpendicular directions (for example, lumber from different types of wood), including the creation of in the test sample the uniform initial content of the solvent distributed in the solid phase (including zero), bringing the flat surface of the sample in contact with the source of the dose of the solvent, pulsed wetting in the given direction of the studied orthotropic material in a straight line with a moving solvent source of constant productivity, performing electrodes of the galvanic converter in the form of straight sections and placing them on both sides of the pulsed humidification line on straight lines parallel to the pulsed humidification line located on the same specified distance from it, measuring the change in time of the EMF of a galvanic converter.

In contrast to the prototype (RF patent 2549613, IPC ¹¹ G01N 27/26, G01N 13/00, 04/27/2015, Bull. No. 12), the diffusion coefficient is measured provided that the maximum signal of the galvanic sensor E _{max of} 0.75 is reached in the experiment -0.95 from the maximum possible value of this signal E _e corresponding to the transition of the solvent from the region of the material under study connected with the solid phase to the region of the free state, time instants τ ₁ and τ ₂ at which the same values of the signals of the galvanic sensor E ₁ and E are achieved ₂ of dia azone (0.7-0.9) E _e, respectively on the ascending and descending branches of the curve of the signal changes over time, and the calculation of diffusion coefficient by the formula:

where r ₀ is the distance between the electrodes of the galvanic converter and the line of exposure to a dose of solvent on the surface of the controlled product.

Moreover, if after applying the pulse with a dose of solvent, the maximum value of the signal of the galvanic converter E _max is observed outside the range (0.75-0.95) E _e , then the signal of the converter is expected to decrease to the initial value, and then a new pulse effect with an increased or decreased dose solvent, and this procedure is repeated until the maximum value of the converter signal falls within the specified range, after which the desired diffusion coefficient is calculated.

The essence of the proposed method consists in the following: a probe with a pulsed linear mass source and located on both sides of the pulse line on straight lines parallel to the pulse line at the same given distance is pressed onto the flat surface of a massive product with a uniform initial distribution of solvent (including zero) from it the electrodes of the galvanic converter in the form of straight sections.

The probe has a straight groove in which a linear pulsed solvent source is placed. After applying a pulse with a dose of solvent, the source is removed from the probe, the straight groove is sealed with a plug, and the probe itself provides waterproofing of the sample surface in the source area and the adjacent solvent distribution control area. After applying the pulse - the dose of the solvent (instantly “moisturizing” the surface line of the product), the EMF of the galvanic converter is fixed over time.

To ensure control of the diffusion coefficient of the solvent in different directions of the orthotropic material, the impulse line is oriented in the given direction of the material (for example, when examining lumber - along and across the wood fibers). This provides unidirectional mass transfer in the desired direction, not distorted by mass transfer in the direction perpendicular to the studied direction. Due to this, the control accuracy and the ability to determine the diffusion coefficient of solvents in various directions of the orthotropic capillary-porous material are increased.

The dimensions of the flat section of the product along and across the fibers of the orthotropic material, as well as the length of the line along which the pulsed action is applied, is selected from the condition of exceeding the value (20 r ₀ + r ₁ ), where r ₀ is the distance from the line of electrodes of the galvanic converter to the line of application pulse exposure; r ₁ - the size of the rectilinear segments of the electrodes of the galvanic converter in contact with the surface of the product on lines parallel to the pulse line. When the thickness of the product is more than 10 r _{0, the} process of propagation of the solvent in a massive product after applying such an impulse is described by the boundary-value problem of mass transfer in an unlimited medium when applying a pulsed action from a linear mass source. The change in the solvent concentration U (r ₀ , τ) at a distance r from the source is described by the equation:

where W is the power of the “instantaneous” mass source, acting at the origin r = 0, calculated as the ratio of the dose of the solvent (summed up to the controlled product) to the length of the pulse line L; D is the diffusion coefficient of the solvent; ρ ₀ is the density of the absolutely dry test material; τ is the time.

The diffusion coefficient of the solvent is related by the ratio:

where τ _max is the time corresponding to the maximum on the curve U (r ₀ , τ) of the moisture content at a distance r from the source.

The calculated dependence for determining the desired diffusion coefficient is obtained on the basis of the following studies. After pulsed exposure with a solvent dose at a given distance r ₀ from a linear source, a change in concentration is observed in the form of characteristic curves having an ascending branch from the beginning of the pulsed exposure to the moment τ _max and a descending branch observed after the moment τ _max . In this case, the same concentration values U ^* achieved at time instants τ ₁ and τ ₂ respectively on the ascending and descending branches of the concentration variation curve in time can be determined from expression (1) taking into account (2):

Dividing (3) by (4) leads to the following expression:

From (5) we obtained

From (6), taking into account (2), a calculated expression is obtained to determine the desired diffusion coefficient:

To determine the desired diffusion coefficient in the proposed method, the measurement at time instants τ ₁ and τ ₂ is not subject to the concentration U (r ₀ , τ), but the associated emf of the used galvanic converter in the absence of a static characteristic previously found as a result of calibration. To increase the accuracy, it is necessary that at these times τ ₁ and τ _{2 the} measured EMF value should be on the middle (rational) section of the static characteristic, characterized by a stable converter signal and high sensitivity to concentration changes. Studies show that a rational section of the static characteristic corresponds to a change in the converter EMF in the range:

where E _e is the converter signal corresponding to the transition of the solvent from the region of the investigated material bound to the solid phase to the region of the free state.

The figure 1 shows the curves of the change in the EMF of the converter at a distance of 4 mm during the diffusion of moisture in the cement-bonded particleboard (in relative units to the maximum possible EMF of the converter E _e at the control temperature) at various introduced doses of the solvent pulse (water). Studies show that the values of time instants τ ₁ and τ ₂ corresponding to the EMF values of the transducer from the range (8) are reliably fixed provided that in the experiment the maximum signal of the galvanic sensor E _max is approximately 0.75-0.95 of the maximum possible value signal E _e (figure 1, curves 2, 3). On curve 2 (figure 3) these are time instants τ ₁ 'and τ ₂ ', on curve 3 these are instants of time τ ₁ '' and τ ₂ ''.

When implementing the proposed method, the first pulse is applied with a dose of solvent and the change in the EMF of the galvanic converter is recorded at a predetermined distance from the pulse application line. If the maximum emf value E _max achieved in the experiment is approximately 0.75-0.95 of the maximum possible signal value E _e , then the experiment is completed at time τ ₂ when the experiment reaches the emf value of the converter from the range (8) equal to the emf value at time τ ₁ , after which the value of the desired diffusion coefficient is calculated by the formula (7).

If, after applying the first pulse, the maximum value of the converter signal E _max is observed outside the range (0.75-0.95) E _e , then the converter signal is expected to decrease to the initial value, and then a new pulsed action is carried out with an increased or decreased dose of the solvent, and this the procedure is repeated until the maximum value of the converter signal reached after applying a new pulse falls within the specified range (0.75-0.95) E _e .

After this, the experiment is completed at time τ ₂ when the experiment reaches the value of the EMF of the converter from the range (8) equal to the value of the EMF at time τ ₁ , and then, by the formula (7), the value of the desired diffusion coefficient is calculated.

As an example, the table shows the results of 20-fold measurements of the diffusion coefficient of moisture across the fibers of a cement-bonded particleboard 36 mm thick with a dry density of 1320 kg / m. cube

The distance from the linear source of the dose of the solvent to the location of the electrodes of the galvanic converter is 4 mm. The calculated value of the EMF corresponding to time instants τ ₁ and τ ₂ is approximately 0.7

E _e ; E _max ≈0.75 E _e .

The error of the measurement result is equal to half the confidence interval and was determined as follows:

- математическое ожидание случайной величины; t_α,n - коэффициент Стьюдента при доверительной вероятности α и количестве измерений n; S_n - среднеквадратическая погрешность отдельного измерения:Where

- mathematical expectation of a random variable; t _{α, n} is the Student's coefficient with confidence probability α and the number of measurements n; S _n - the standard error of an individual measurement:

Experimental studies showed that the random error in determining the moisture diffusion coefficient in a cement-bonded particleboard during twenty-time tests (t _{α, n} = 2.1 at α = 0.95) is 6.6≈7%. The duration of the experiment did not exceed 88 minutes.

Claims (4)

1. The method of determining the diffusion coefficient in bulk products from orthotropic capillary-porous materials, which consists in creating a uniform initial content of the solvent distributed in the solid phase in the test sample, bringing the flat surface of the sample into contact with the solvent dose source, and pulsed wetting in the specified direction of the studied orthotropic material in a straight line with a moving solvent source of constant productivity, performing electrodes of galvanic conversion in the form of rectilinear segments and placing them on both sides of the pulse humidification line on straight lines parallel to the pulse humidification line and located at the same predetermined distance from it, measuring the time variation of the emf of the galvanic converter, characterized in that the diffusion coefficient is measured provided that the experiment of the maximum signal of the galvanic sensor E _{max of} 0.75-0.95 of the maximum possible value of this signal E _e corresponding to the transition solution For example, from the region of the material under study connected with the solid phase to the region of the free state, the time instants τ ₁ and τ ₂ are fixed at which the same values of the signals of the galvanic sensor E ₁ and E ₂ are achieved from the range (0.7-0.9) E _e, respectively on the ascending and descending branches of the curve of the signal in time, and the diffusion coefficient is calculated by the formula:

where r ₀ is the distance between the electrodes of the galvanic converter and the point of exposure to a dose of solvent on the surface of the controlled product. 2. The method of claim. 1, characterized in that when the maximum value signal of the electrochemical converter E _max after applying the pulse of the solvent dose not within range (0,75-0,95) E _e expected to decrease transmitter signal to the initial value, and then carry out a new pulsed action with a moving solvent source of constant productivity with an increased or decreased dose of the solvent, and this procedure is repeated until the maximum value of the converter signal enters the specified range azone, after which the desired diffusion coefficient is calculated.

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