FI71617C - DIRECTIVE REQUIREMENTS SPECIFIC TO THE MECHANICAL MASSOR. - Google Patents

Description

ANNOUNCEMENT CA A CA Π W® B 11 UTLÄGG NI N GSSKRIFT / IOI / ^ (45) P-'i tenV: 1 iur .: tty (51) Kv.lk. * / Lnt.CI. * G 01 N 15 / 06 FINLAND —- FINLAND (21) Patent application - Patentansökning 8 0 1 k '/ 6 (22) Application date - Ansökningsdag 0 7.0 5.8 0 (23) Starting date - Giltighetsdag gy gg gg (41) Publication - Blivit offentlig gg ^ j gg

National Board of Patents and Registration Date of publication and publication.

Patent and registration authorities Ansökan utlagd och utl.skriften publicerad 10 10.86 (86) Kv. application Int. ansökan (32) (33) (31) Privilege requested - Begärd priority gg gg yg

Canada (CA) 327137 Proven-Styrkt (71) Domtar Inc., P.O. Box 7210, Montreal, Quebec, Canada (CA) (72) Alkibiadis Karnis, Dollard des Ormeaux, Quebec,

Paul M. Shall Horn, Vaudreuil, Quebec, Canada (CA) (7I4) Berggren Oy Ab (54) Direct control of specific surfaces of mechanical masses - Directing on the specific age of the mechanical mass of Mecan iskä massor

The present invention relates to a method and apparatus for continuously determining the specific surface distribution of fibers in a pulp.

"Mechanical pulps" means pulps produced primarily by mechanical treatment, with or without chemical or physical auxiliary steps. Such masses are e.g. conventional abrasive grinders ground in a grinding wheel or grinder and pulps made by various chemimechanical and thermomechanical processes.

It has been shown in the art that the fibrous properties of mechanical pulp, which determine the strength, optical and printing properties, include e.g. (a) the average surface area of the fibers, which is important in determining the strength properties of the mechanical pulp (tear, tensile, puncture, wet web strength, etc.) and some printing properties such as breakthrough, ink absorption, which also significantly affect paper opacity and whiteness; the specific surface distribution of the fibers, which affects the printing properties, such as fiber fluff.

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It is proposed to use at least two measurement methods for the direct determination of the slurry surface of a mass, which measure other properties of the mass, but in which each measurement is affected by a specific surface and in which simultaneous equations are solved so as to obtain the mass of the mass. This method was further complicated by the fact that the consistency measurement was not: an actual measurement and it also reflected the specific surface properties, so three simultaneous equations had to be solved in order to find out the specific surface area (average specific surface) of the mass. Such a method is disclosed in U.S. Patent No. 3,802,964.

Most specific surface measurements use the permeability method, but such methods are not very suitable for direct measurements.

It is an object of the present invention to provide a method and apparatus for the continuous determination of the surface area distribution of the fibers of a pulp.

In general, the present invention is directed to a method and apparatus for determining the specific gravity distribution of fibers in a pulp. The method is characterized in that a feed sample of said mass is continuously divided in an hydrocyclone into an upstream fraction and a downstream fraction, the amounts and specific surfaces of at least two of said feed fraction and each said fraction are measured, and the specific gravity distribution of said feed fraction is determined based on said feed fraction and to the cumulative normal distribution ratio as a percentage of the input of the cumulative specific surface area of the ili strip between the fraction and the specific surface area. The apparatus comprises a hydrocyclone device having an upstream and downstream line, means for feeding pulp to the hydrocyclone to divide the pulp into downstream and upstream fractions, means for measuring the specific surface area and quantities of said feed upstream and downstream fractions; and the cumulative normal distribution ratio as a percentage of the input between the cumulative specific surface fraction and the specific surface area.

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The invention also relates generally to a method for directly determining the specific surface area of a pulp suspension by measuring the light scattering properties of the pulp suspension and thereby measuring the turbidity of the suspension, measuring the consistency of the suspension and determining the average surface area of the pulp suspension based on the specific surface area and the measured turbidity reading.

Other features, objects and advantages of the invention will become apparent from the following detailed description of preferred embodiments of the invention with reference to the accompanying drawings, in which Figure 1 schematically shows a monitoring system according to the invention, Figure 2 is a graph showing specific surface area m2 / g compared to Jackson turbidity units (JTU). and the effect of the change in consistency on the relationship between the specific surface area and the turbidimeter reading, Fig. 3 schematically shows the turbidimeter, and Fig. 4 is a graph showing the cumulative weight fraction as a percentage of feed relative to the specific surface area m2 / g of normal verification paper.

As shown in Figure 1, the pulp sample taken from the mechanical process enters the system via line 10 and, depending on the point in the mechanical pulping system from which the sample is taken, passes through the latency remover 12 and then enters the tank 14 via line 16.

A suitable principle for releasing the latent properties of mechanical pulp relatively quickly is used in a laboratory disintegrator sold under the name "Domtar Desintegrator" by Noram Quality Control and Research Equipment Ltd. This device releases the latent properties of the mechanical pulp by circulating the pulp through a centrifugal pump (at a pulp temperature of approx. 90-95 ° C ’).

The pulp from the tank 14 is pumped through the pump 18 to the consistency meter 20 and returned to the tank 14 via the line 22.

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The consistency meter 20 used in the direct monitoring system is required to measure consistency independently of other fiber properties (i.e., fiber length and specific surface area) and to be able to measure absolute consistencies with an accuracy and repeatability of + 5% of absolute value. Thus, in the consistency meters used in the present invention, the principle of determining the consistency must be straightforward, i.e., it must be based on the determined consistency. Most consistency meters measure consistency indirectly, i.e., they measure other mass properties such as flow resistance, dielectric properties of the pulp slurry, etc., which are proportional to the consistency as well as other than-judgments.

Methods have been proposed to determine the consistency of a pulp without other properties of the pulp by directly measuring the density of the pulp slurry. For example, Thiessen and Dagg have proposed measuring vibrations from an unbalanced rotor to determine the density of a fluid relative to a reference fluid using a rotating sample container and determining system imbalance (see Pulp & Paper Magazine of Canada, September 1959).

It has also been proposed to use the Sperry Gravitymaster for indirect determination of consistency independently of other pulp properties. This instrument uses the self-equilibrium method to determine the variable weight of a sample of a specified size (see Measurement and Control, No. 1 / 11.11. 1968, pp. T179-T186).

Neither of the above devices is known to be commercially available.

If the consistency is to be measured directly using either of the above methods or the method proposed below, it is important that the sample be substantially free of foreign matter or contain known amounts of it. In particular, it is important that the sample does not contain air and that any foreign matter (fillers, etc.) contained in the fibers is accurately known before the consistency is measured. It is also important that the temperature is precisely controlled or known as 71617, as a change in temperature changes the accuracy of the instrument, although the Kojo can be calibrated for different temperatures.

It has now been found that a device known as the density constant, e.g. sold under the trade name "Dynatrol" Cl-IOHY and manufactured by Automation Products, Houston, Texas, can give a very accurate reading regardless of the consistency of the pulp. This device measures the change in frequency of the oscillating tube through which the pulp slurry is continuously passed, thus obtaining a continuous reading of the stock consistency for stock stock densities in the range of about 0.1-1.5 t, which is the consistency range in which the present invention operates.

The consistency meter 20 measures the consistency of the stock in the tank 14 and preferably controls the supply of water free of fibers and other solids through the line 24 via the control valve 26 so that the consistency of the stock in the tank 14 remains substantially constant.

The dashed lines used in Figure 1 indicate the control lines from the different means to the different elements monitored and the main controller.

It is observed that the consistency meter 20 is connected to the valve 26 by a control line 30 and to the main controller 28 by a line 32. If the consistency of the tank 14 is always kept constant, the control line 32 can be omitted because it is not variable in the system.

The stock of the tank 14 is also circulated through the pump 34 through the specific surface meter 36 and returned to the tank 14 via the line 38. The specific surface meter 36 directs the signal to the main controller 28 via the control line 40. This gives the average surface area of the pulp.

In general, specific surface meters use the transmission method to determine the specific surface. However, such a method is not particularly suitable for direct measurement.

An optical method for measuring stray light from a mass sample has been found to be a more suitable method for measuring the specific surface area. It is thus a device known as a turbidimeter, which is normally used to determine the solids concentration of a sludge. The light scattered from the fiber aggregate of the pulp sample can be considered to be proportional to the number of particles per unit volume of suspension and their surface area, i.

T = ΚΝΆ where T is the amount of stray light (meter reading), K = constant depending on the refractive index of the fibers and their size in relation to the wavelength of light used, N = number of particles and A = mean area of the particles. The stock of a stock is C - Nm, where m is the average mass of the particles, so that T = KC (A) m and the term A is the area per unit mass, i.e. the specific surface area of the particles, so

T = KC (SS) or (SS) = T 9 9 KC

where (SS) g is the central characteristic surface of the fiber network. The index (g) is used to denote the geometric specific surface or light scattering area in contrast to the hydrodynamic specific surface measured by the transmittance method. Although the two characteristic surfaces may not be numerically the same, there is a definite correlation between them.

For 130 pulp samples, which included groundwood, refining pulp and hot milling, chemical pulps, and mixtures of chemical fibers and groundwood, the experimental results were correlated with the following regression equation.

(SS) = 8.92 x 10 "7 (JTU) 1-77- (C) ~ 2 · 16 2 where (SS) is the average (hydrodynamic) specific surface area of 2 m / g, JTU is the opacimeter reading in Jackson turbidity units and Cg is the percentage consistency The coefficient of determination for R2 equation 2 is 0.88, indicating that the variations in the 88 V, specific surface area are explained by the variations in JTU and Cg.

Figure 2 is a graph of Equation 2 at different densities and shows the observed relationship between the specific surface area and the turbidimeter reading. It is observed that the turbidity meter provides an easy and fast method of operation for determining the specific surface area of a mass sample.

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The light scattering ratio of the mass can be measured with a commercially available turbidimeter 1a. The model used in the present invention is a DRT-1000 direct turbidimeter manufactured by HF instruments, Bolton, Ontario. Turbidimeters generally conduct a beam of light through a suspension and measure scattered light on opposite sides of the beam of light (at an angle of 90 ° to the beam) as well as light projected through the suspension (in line with the beam of light).

Figure 3 schematically shows a turbidimeter equipped with a light source 200 that conducts light through a lens 202 and a sample 204 that continuously flows through a transparent tube portion 206. Three detectors 208, 210 and 212 are adapted to detect light reflected from and passing through the sample, i.e., detectors 208 and 210 detect reflected or scattered light on opposite sides of the sample, and detector 212 detects light that has passed the sample. The light source 200, the tube 206 and the detector 212 are in a straight line, and the detectors 208 and 210 and the tube 206 are also in a straight line, the two lines thus formed being substantially perpendicular to each other.

The specific surface meters used in the present invention, such as meter 36, are in fact turbidimeters used in connection with the consistency meter to determine the specific surface area of the pulp fraction or feed mass based on e.g. the curves shown in Figure 2.

The consistency meter 20 and the specific surface meter 36 (turbidity meter) indicate the consistency and specific surface of the feed mass.

The pulp is pumped by pump 34 via line 40 to specific surface area means, generally designated 42, which include a hydrocyclone 44 having an upstream (bottom) outlet line 46 and a downstream (peak) outlet line 48. A consistency meter 50, a specific surface area meter 52 ( turbidimeter) and flow meter 54 measure consistency, specific surface area, and flow rate through the upstream line 96, respectively. The outputs of these meters are fed through lines 56, 58 and 60, respectively, to the main controller 28, and the stock in line 46 is returned to the system via line 62.

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The consistency and specific surface area of the downstream fraction of line 48 can also be measured with a consistency meter 64 and a specific surface meter 11a 66 (with a turbidity meter). The outputs of these meters are fed through lines 68 and 70, respectively, 70 to the main controller 28, and the stock in line 48 is returned to the system via line 62.

The flow to the means 42, and in particular to the hydrocyclone 44, is controlled by a control flow meter 72 which, via line 74, controls the valve 76 and thus the flow through line 40.

The output of the flow meter can be connected to the main controller 28 via line 78, but if the flow to the hydrocyclone 44 is kept substantially constant, direct flow from the flow meter 72 to the main controller 28 is apparently not required.

The consistency in line 48 or 46 can be calculated because the consistency and flow of the stock entering the system are known, and the consistency and flow of the stock in line 46 or 48 is determined.

The means 42 feed the upstream specific surface and the weight fraction to the main controller, while the downstream fraction and the specific surface of the feed mass are obtained via the meter 36.

One laboratory method for determining the specific surface area uses a hydrocyclone device in which the sample is allowed to flow as a cascade and the weight fractions and specific surface area of the different downstream and / or upstream fractions are measured to determine the fiber specific surface area distribution curve. When such mechanical or chemimechanical pulp data are plotted on cumulative normal probability paper as a cumulative specific surface area fraction as a percentage of the feed relative to the specific surface area, it has been found to approach a linear relationship over a significant range of pulp fiber specific surface areas. In principle, therefore, only two points are needed to determine the total specific surface distribution of the fibers in this region.

Typical probability curves for the specific surface are shown in Figure 3. These curves were obtained from laboratory data and have an exact linear relationship to the cumulative

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9 71 61 7 between the specific surface fraction (as a percentage of the input) and the specific surface marked on the cumulative probability paper. Open and closed circles mean two different hot rubs and open and closed triangles mean two different grinds.

In the direct sensor of the present invention, the main diameter of the hydrocyclone was 51 mm and the cyclone was provided with a downstream opening of 7.9 mm. Feed flow, consistency and specific surface area (turbidity) and downstream and upstream fractions are measured (or calculated) using input data to main controller 28 from consistency meter 20, flow meter 72, consistency meter 50, specific surface meter 52, flow meter 54, viscosity meter 64 and specific surface 66 the ratio can be obtained from the distribution of the specific surface area over the range as well as the low specific surface fraction of the pulp, which is important for the determination of the fiber fluff.

Alternatively or as a check, the feed specific surface measured by meters 36 and 20 and its flow (meter 72) and the upstream specific surface measured by meters 62 and 60 and its flow (meter 64) (or downstream line 48) can be used to obtain the desired points on the curve. Any two fractions downstream, upstream or inlet can be measured to give the desired two points on the hydrocyclone material balance.

It will be appreciated that the mass surface area distribution and center characteristic surface may be obtained using means 42 (or selected portions thereof) and that the mass sample used to determine these parameters is returned to the system via lines 46 and 48 connected to line 62.

The invention may be modified without departing from the spirit of the invention as defined in the appended claims.

Claims (7)

1. A method for continuously determining the weight distribution of the specific surface of the fibers in a pulp, characterized in that a sample flow of the pulp in a hydrocyclone device (44) is continuously divided into an overflow stream and an underflow stream, so that the amount and specific surface area of the pulp two of the flows are measured and the weighted distribution of the specific area of the sample flow is determined on the basis of the measured quantities and specific surfaces for at least two of the flows and a generally cumulative normal distribution ratio between that expressed as a percentage of the flow, with a specific specific area provided, cumulative fraction and specific surface area. 12 71617 2. Device for continuously determining the weight distribution of the specific surface of the fibers in a pulp, characterized by a hydrocyclone device (44) having an overcurrent outlet (46) and an undercurrent outlet (48), a means (34). , 40) for feeding pulp to the hydrocyclone device (44) for dividing the pulp into an overflow stream and an underflow stream, means (50, 52, 54, 64, 66, 72) for measuring the amount and specific surface area of at least two of the said sample, overcurrent and undercurrent flows and a calculation means (28) for determining the distribution of the specific surface of the fibers in the pulp on the basis of the measured surfaces and currents and a cumulative normal distribution ratio between that expressed as a percentage of the flow, with a specific surface area, cumulative fraction and surface area. Device according to claim 2, characterized in that each means for measuring said quantities comprises a means (72, 54) for measuring the flow rate and a means (50, 64) for measuring the mass concentration, the means for measuring the flow rate. the concentration gives the concentration measure essentially independent of the other properties of the pulp. Device according to claim 2, characterized in that each means for measuring the specific surface is a means (50, 64) for measuring the concentration of the pulp independent of the other properties of the pulp and a means (52, 66) for measuring the turbidity of the pulp. . Device according to claim 4, characterized in that the means (52, 66) for measuring the turbidity measure scattered light reflected from the mass.