EP1949095A2

EP1949095A2 - Apparatus for the measurement of a streaming potential of a liquid containing solid matter

Info

Publication number: EP1949095A2
Application number: EP06840940A
Authority: EP
Inventors: Markus Mornhinweg
Original assignee: BTG Instruments GmbH
Current assignee: BTG Instruments GmbH
Priority date: 2005-11-17
Filing date: 2006-11-14
Publication date: 2008-07-30
Also published as: WO2007057160A2; US20080315863A1; WO2007057160A3

Abstract

Disclosed is an apparatus for measuring a streaming potential of a liquid containing solid matter. Said apparatus comprises a first electrode device relative to the direction of flow, said first electrode device being provided with a first rod-shaped electrode, as well as a second electrode device encompassing a second rod-shaped electrode, and a filter device located between the electrode devices. In order to improve the reproducibility and stability of the test results, the first electrode is embedded in a wall of a duct of the first electrode device so as to protrude into the duct by a maximum of half the diameter thereof perpendicular to the direction of flow.

Description

Device for measuring a flow potential on a solids-containing

liquid

description

The invention relates to a device for measuring a flow potential on a liquid containing solids according to claim 1.

In the case of interactions at boundary layers, which occur, for example, in solid suspensions in a wide variety, the zeta potential plays a decisive role in addition to the surface energy. The zeta potential is a measure of ionic attachment processes at the boundary layer and indicates how strongly ions are bound. Furthermore, the zeta potential serves as a parameter for acid-base properties of fiber and powder surfaces. In this case, the zeta potential may possibly be neutralized by an accumulation of ions at the interfaces in the interface between the solid surface and the fluid and therefore also serves as a measure of the stability of suspensions and emulsions.

In industry, the zeta potential of the starting materials is used in particular in microencapsulation processes to optimize the process flow in order to make the most optimal selection of suitable additives for the microencapsulation process and thus to be able to increase the efficiency of the encapsulation process.

Furthermore, the measurement of the zeta potential plays a decisive role, in particular in papermaking. Here are synthetic sizing agents such as Alkylketene dimer (AKD) and succinic acid (ASA) used as a hydrophobing agent. The sizing systems often have different zeta potentials and thus different properties, so that the papermaker must weigh which is the optimum sizing agent for his paper machine or for the respective paper product. In particular, the zeta potential of the fibers present in the pulp plays a decisive role. In particular, in the production of waste paper, the zeta potential of the fibers in the pulp is different in batches, since the composition of the raw materials (waste paper) of the pulp varies constantly. Therefore, particularly in the production of waste paper, the zeta potential of the pulp must be continuously determined in order to be able to add suitable sizing agents and additives. The zeta potential plays a crucial role.

Usually, the zeta potential is determined by the flow potential method. First, the flow potential and the conductivity of the suspension are measured, from which the zeta potential is subsequently determined. The

Flow potential method is a physical-surface analytical method for characterizing the electrokinetic properties of solids in contact with aqueous solutions. If a solid is in contact with an aqueous electrolyte solution, then there is a different distribution of the electrical charge at the phase boundary than in the interior of the liquid phase. The accumulation of charge carriers at the phase boundary leads to the formation of an electrochemical double layer: the charge carriers located on a solid surface are compensated by counter ions, which are partly in a rigid arrangement and partly in a diffuse distribution in the liquid. To determine the zeta potential according to the flow potential method, a fluid movement is generated in a measuring cell in which there is a capillary system by a driving pressure. Depending on the flow resistance in the flow channel, a pressure drop occurs at the measuring cell. The electrolyte flow causes a charge shift along the flow channel in the direction of flow, since only the mobile ions in the diffused layer but not in the rigid layer absorb ions as a result of Stokes

Friction be entrained in the flow direction. The resulting potential difference is detected by measuring electrodes located at the two ends of the flow channel. The zeta potential is approximately equal to the potential of a boundary between rigid and diffuse layer and can be calculated from the measured flow potential.

According to the prior art, different devices for zeta potential determination by the flow potential method are known. With regard to paper production, these devices are designed to detect the electrokinetic properties in chemically "pure" pulps, ie pulps whose starting materials are high quality and new paper fibers Pulp loaded with only a few chemical additives (printing ink, sizing agent, bleach, etc.), so that due to a low chemical reaction or the like interaction in the pulp, the Zetapotentialbestimmung usually can be applied easily, with the actual measurement signal, namely the flow potential, clearly different from the possibly existing interference signal.

US Pat. No. 4,535,285 discloses a method for measuring the flow potential within a fiber-containing liquid, wherein a multiplicity of flow paths of the liquid are produced by a filter cake and the flow potential arising via the filter cake is stored as a potential measurement series. The multiplicity of flow paths of the liquid are repeated at a frequency periodically. The known method also has the method step of storing the flow profile as a flow measurement series. Furthermore, the publication discloses a device for measuring the flow potential within the fiber-containing liquid, wherein a multiplicity of flow paths of the liquid are produced by the filter cake and the flow potential arising via the filter cake is stored as a potential measurement series. For this purpose, a flow-through line, which is closed by a filter, a flow-generating device for conveying the suspension through the line and for producing the filter cake on the filter and an electrode arrangement for measuring over at least parts of the filter cake electrical potential provided. Furthermore, the conventional device has a flow measuring arrangement for detecting and storing a flow measuring series, a computing device for deriving the Height of the flow potential and a flow device for controlling the flow path.

The publication "Zeta Potential Experiences with Laboratory and On-line Measurements" by ROHLOFF E, HÖSCHLE O. discloses a method for measuring the

Flow potential within a fluid-containing fluid and a device for measuring a flow potential within a fiber-containing fluid. The known device comprises a flow-through conduit, which is closed by a filter; a flow generating means for conveying the suspension through the conduit and for producing the filter cake on the filter; and an electrode assembly for measuring the electrical potential applied across at least portions of the filter cake. In addition, it is known from the publication, a flow measuring arrangement for detecting and storing a flow measuring series; a computing device; and to provide a control device for controlling the flow path.

From DE 102 00 654 Al a device of the type mentioned is known. The problem with this device is that the reproducibility of the measurements often leaves something to be desired.

The invention is based on the object of developing a device of the type mentioned in such a way that the reproducibility of the measurement results is improved.

This object is achieved by a device according to claim 1.

In particular, this object is achieved in a device for measuring a flow potential on a liquid containing solids having a first electrode means in the flow direction with a first staB shaped electrode and a second electrode means with a second rod-shaped electrode and with a

Detached filter between the electrode devices. Preferably, the first electrode is so in a wall of a flow channel of the first electrode means let in that it protrudes maximally with its diameter, preferably with half of its diameter in the flow channel transverse to the flow direction.

Surprisingly, it has been shown that a significant increase in the reproducibility of the measurement results is achieved by this arrangement and design of the two electrodes, including that electrode which is in the liquid containing the solids. The cleaning of the arrangement is greatly facilitated.

Preferably, at least the first electrode has a round cross-section. Such a round cross section is particularly easy to manufacture.

At least the first electrode is preferably made of a drawn wire. When pulling wires, it is possible in a simple manner to produce a uniform and, above all, very smooth surface.

In order to achieve a good reproducibility of the measurement results in a single measuring device with exchangeable electrode devices as well as in a multiplicity of measuring devices with such electron bottom devices, the first and the second electrodes, in particular, are all preferably produced from a single batch of drawn wire. As a result, a considerable and hitherto impossible increase in the reproducibility of the measurement results of a plurality of devices or devices having a plurality of measuring cells or exchangeable electrode devices can be achieved.

Preferably, the first and / or the second electrode are made of platinum-iridium or drawn from a wire consisting of this material. This material offers surprisingly good results, in particular with regard to the constancy of the measurement results or their reproducibility.

The first and / or the second electrode preferably have a defined surface roughness. When pulling, it is possible to achieve a very smooth surface. But it is also possible, a defined roughness, for example by blasting and / or etching and / or electropolishing the electrode surfaces. In turn, with this defined surface roughness, all electrodes exhibit very similar to the same properties within the measuring cells.

The filter device preferably comprises a replaceable sieve, so that a slight cleaning possibility is given. In addition, the filter device may comprise a paper filter which can be placed on the screen, which is the case in particular when the solids are very small particles.

Preferred embodiments will be apparent from the dependent claims.

Hereinafter, an embodiment of the invention will be described in more detail with reference to drawings. Show here

FIG. 1 shows a plan view of a second electrode device,

FIG. 2 shows a section along the line II-II through the arrangement according to FIG. 1,

FIG. 3 shows a plan view of a first electrode device,

FIG. 4 shows a section along the line IV-IV from FIG. 3,

- Figure 5 is a detail view of the section corresponding to the figure 4 and

FIG. 6 shows a longitudinal section through a measuring cell with the electrode devices.

In the following description, the same reference numerals are used for the same and the same parts acting.

The measuring cell 10 shown in the figures (see in particular Figure 6) has a flow channel 11, which tapers in accordance with the drawings to the top. In this tapering direction, the flow channel 11 is flowed through by the sample liquid.

The sample liquid first flows through a first electrode device 20, which has a holding frame 22 in which an electrode 21 is mounted. Thereafter, the sample liquid flows through an intermediate piece 12 and a second electrode means 30 with a holding frame 32, in which a second electrode 31 is mounted. The holding frame 22 of the first electrode device is connected via a shoulder 24 with the spacer 12 liquid-tight but separable. The holding frame 32 of the second electrode device 30 is liquid-tightly but separably connected via a shoulder 34 with the intermediate piece 12, wherein at the junction, a filter device 40 is attached, which initially comprises an exchangeable sieve. In addition, a filter paper may be placed.

The holding frames 22 and 32 of the first electrode means 20 and second electrode means 30 have concentric bores whose walls 23 and 33 are aligned with a wall 13 of the intermediate piece 12 at the transition areas.

As can be seen in particular from FIGS. 3 and 4, the first electrode 21 is inserted in such a tangential manner to the wall 23 of the first electrode device 20 or its holding frame 22 that its outer surface is half its (or less) its, as shown in FIG Diameter D protrudes beyond the wall 23 and extends into the flow channel 12. To achieve this, a bore for the first electrode 21 is first introduced into the holding frame 32, before the central bore for forming the wall 23 of the holding frame 22 is introduced. In this way, a precise production in a simple manner possible.

The second electrode 31 of the second electrode device 30 is mounted centrally in the holding frame 32, as shown in FIGS. 1 and 2.

The special attachment of the first electrode 21 now causes, after use and even during use, solids which are present in the sample liquid, find no place, in particular no undercut, in which they could get stuck.

The second electrode 31 is downstream of the filter so that solids do not contact them.

This particular arrangement of the first electrode 21 has brought about astonishing advantages over a central arrangement as in the second electrode 31 with it. In particular, the measured values are considerably more stable and reproducible than before.

The material used for the electrodes 21 and 31 is, in particular, platinum-iridium, with drawn wire in particular being used as semifinished product. The drawing process achieves an extremely uniform surface, so that when several (replaceable) electrode devices 20/30 are produced, the achievable measurement data is only within a very narrow tolerance range. There is also no danger that the surface will be damaged or changed during cleaning because the material is very hard.

It should be expressly pointed out at this point that the shape of the electrodes can also deviate from a circular cross-section, if the above-mentioned criterion of tangential intrusion into the flow channel is ensured. Furthermore, a plurality of first electrodes 21 can be used in the holding frame 22, if this is desired for metrological reasons.

LIST OF REFERENCE NUMBERS

10 measuring cell

11 flow channel

12 intermediate piece

13 wall

20 first electrode device

21 first electrode

22 first holding frame 23 first wall

24 paragraph

30 second electrode device

31 second electrode

32 second holding frame

33 second wall

34 paragraph

40 filter device

D electrode diameter

10

Claims

claims

1. Device for measuring a flow potential on a liquid containing solids with a first seen in the flow direction

Electrode device (20) with a first rod-shaped electrode (21) and a second electrode device (30) with a second rod-shaped electrode (31) and with a filter device (40) between the electrode devices (20, 30).

2. Device according to claim 1, characterized in that the first electrode (21) in such a way in a wall (23) of a flow channel (11) of the first electrode means (20) is inserted, that maximum with their diameter (D), preferably a maximum with half of its diameter (D) in the flow channel (11) projects substantially transversely to the flow direction.

3. Device according to one of claims 1 or 2, characterized in that at least the first electrode (21) has a round cross-section.

4. Device according to one of the preceding claims, characterized in that at least the first electrode (21) is made of a drawn wire.

5. Device according to one of the preceding claims, characterized in that a plurality of first and / or second electrode means (20/30) is provided, the first and second

Electrodes (21, 31) are all made from a single batch of drawn wire.

6. Device according to one of the preceding claims, characterized in that the first and / or the second electrode (21, 31) consist of platinum-iridium.

7. Device according to one of the preceding claims, characterized in that the first and / or the second electrode (21, 31) has a defined surface roughness, in particular by blasting and / or etching and / or electropolishing.

8. Device according to one of the preceding claims, characterized in that the filter device (40) comprises a preferably exchangeable sieve.

9. Apparatus according to claim 8, characterized in that the filter device (40) comprises a paper filter placed on the screen.

10. The device according to any one of the preceding claims, characterized in that the second electrode (31) is arranged crossing the flow channel substantially centrally.