DD282376A7 - UNIVERSAL APPLICABLE CONDUCTIVITY CELL FOR FLUIDS OF FLUIDS - Google Patents

Abstract

The invention relates to a conductivity cell for measuring the absolute electrical conductivity of liquids flowing in channels and / or for determining the radial conductivity or concentration spectrum in the flow of components having different electrical conductivities. According to the invention, the conductivity cell consisting of two successively arranged electrode systems is constructed in such a way that the electrode system arranged opposite the direction of flow consists of axially parallel lamellar electrodes with slit-like openings distributed in the direction of flow and uniformly distributed over the length, these openings being associated with the electrodes of the second electrode system, and the width of the lamellar electrodes is at least five times greater than the width of the electrodes of the second electrode system. Fig. 1 {conductivity cell; flowing liquids; Concentration range; Electrode system; lamellar electrodes; slot-shaped OEffnungen}

Description

For this 3 pages drawings

Field of application of the invention

The invention relates to a conductivity cell for measuring the absolute electrical conductivity of liquids flowing in channels and / or for determining the radial conductivity or concentration spectrum in the flow of components with different electrical conductivities. The invention can be used in a large conductivity range and is suitable for monitoring flow processes with the aim of determining radial flow profiles in channels.

Preferred applications are related to reaction and mixing processes as well as research.

Characteristic of the known technical solutions

Various embodiments of measuring cells for determining the electrical conductivity of fluid media are known. These arrangements include at least two electrodes which, due to their geometry, i. H. their distance and the opposite effective areas, define a cell constant. The electrical conductivity is determined as the product of the measured conductance (reciprocal resistance) and the cell constant, the size of the measured conductivity being determined by the cell constant for a given product conductivity.

A flow cell of this type is z. As described in DE-AS 1698213. A perforated plastic disc dissociates two electrodes, which are formed by a noble metal coating of the plastic disc and the adjacent metal housing parts. Basically, with such an arrangement, the electrical conductivity strömander media can be determined, but with the restriction that only one cell constant is realized in this cell. This results in the disadvantage that, for large changes in conductivity, either the measuring circuit (measuring range) has to be changed or a measuring cell with modified cell constant adapted to the measuring range must be used. With the arrangement according to DE-AS 1698213, the measurement of different electrical conductivities over the pipe cross-section (radial conductivity spectrum) is furthermore excluded. This case is z. B. of interest when two or more liquids of different electrical conductivity in channels are brought into contact and the degree of their mixing is to be judged on the basis of the radial conductivity spectrum.

The measuring cell according to DD-WP 220214 pursues the goal of detecting the electrical conductivity in a large conductivity range by means of several installed cell constants. However, this arrangement is radial for the detection. Conductivity differences unsuitable because it is an integral measuring principle. The illustrated concentric electrode arrangement with circular segment-shaped internal electrodes has the following disadvantage:

With increasing differences between the cell constants, which arise due to different areas of the Inrenelektroden, the number of possible electrode pairs is reduced. Conversely, if many electrode pairs are to be installed, the difference between their cell constants remains small.

US Pat. No. 4,644,263 discloses a method and apparatus for determining the composition of flowing liquid mixtures whose components have different electrical conductivities. The measuring cell consists of a large number of horizontal and vertical wires, which form a given grid of intersections.

If conductivity spectra over the pipe cross-section are determined with this arrangement, it proves to be disadvantageous that vortices are induced by the electrode wires lying opposite to the direction of flow, which cause that "effective mixture conductivities" in the region of the electrode gap are always measured However, in the determination of local electrical conductivities at the individual measuring locations.The spatial resolution of the conductivity values and thus the accuracy remain low.

If the conductivity values determined in this way are used as a synonym for the mixing state of the flow, an already homogeneous mixture is simulated. This disadvantageous influence is greater, the better the liquids are miscible with each other.

In the determination of conductivity spectra over the pipe cross-section, only one cell constant (formed by the spacing of the wire planes and the effective area at the intersections) is given, so that the detection of different conductivity ranges requires either separate Meßzdllen or equipment technical effort.

Aim of an invention

The aim of the invention is to increase the reliability of the measurement results and to reduce the technical equipment and the operating effort in the measurement of electrical conductivities flowing liquids.

Explanation of the nature of the invention

The invention has for its object to provide a universally employable conductivity measuring cell for flowing liquids, which largely excludes flow interference on the measurement result and simultaneously includes different cell constants. In particular, existing large transverse flow components should be attenuated (laminarized) and already laminar flow states with safe avoidance induced by the measuring cell vortices, and remain unaffected while high variability of the measuring cell.

According to the invention, the object is achieved in that the universally applicable conductivity cell for flowing liquids from an oppositely arranged to the flow direction electrode system of axially parallel lamellar electrodes with pointing in the flow direction and uniformly distributed over the length slot-shaped

Openings exists, these openings are associated with the electrodes of the second electrode system. The width of the lamellar electrodes is at least a factor of 5 greater than the width of the electrodes of the second electrode system.

For a further embodiment of the invention is provided, the arrival and trailing edges of the lamellar electrodes flow favorable, z. B. by attaching a chamfer perform. It is also possible to design the electrodes of the second electrode system as lamellae.

In order to provide several different cell constants, an off-center arrangement - at least the second electrode system - within the frame is provided.

With the arrangement according to the invention 4 different cell constants can be realized in a simple manner.

In addition, in another embodiment, in addition, a mutual axial rotation of the electrode systems is possible, which leads to a further increase in the variability of the measuring cell.

Despite the high installed variance of the cell constants, the electrode systems exert no negative influence on the liquid flow. On the contrary; turbulent flow is smoothed and laminar flow is not disturbed.

embodiment

In the following some embodiments of the invention will be explained in more detail. Showing:

Fig. 1: Conductivity measuring cell with the electrode systems 4,5 which are each housed in separate frames 6.7, wherein the

Frames 6.7 separated, d. H. not in the installed state, are shown

 Fig. 2: Conductivity measuring cell according to Figure 1 in the installed state, Fig. 3: Conductivity measuring cell with lamellar electrodes 10, with a small distance between the

4 and 8. The conductivity measuring cell according to FIG. 3, wherein a large distance between the electrodes 8, 10 is realized.

The conductivity cell shown in Figure 1 includes two electrode systems 4, 5 which are housed in separate frames 6,7. The electrode system 4 lying opposite to the flow direction 3 is constructed from axially parallel lamellar electrodes 8 with slot-shaped openings 9, while the electrode system lying in the flow direction 3 consists of parallel wire-shaped electrodes 10 which run in the slot-shaped openings 9 in the installed state. The width of the electrodes 8 is at least a factor of 5 greater than the width of the electrodes 10. The lamellar electrodes 8 cause a laminarization of the flow, which suppresses large cross-flow components in the incoming turbulent flow and already maintain laminar flow conditions. The induction of vortices by the conductivity cell is avoided.

Is there now the liquid mixture to be analyzed from components of different electrical conductivity, which z. B. is the case when a component was marked with the target conductive to determine the state of mixing - for example, behind a tubular reactor - on the basis of the conductivity spectrum, locally different conductivity values can be determined at the intersections of the electrodes 8, 1C. The solution according to the invention stabilizes the concentration profile, so that at the measuring location, the gap between the electrodes 4, 5 the same concentration profile as at the reactor outlet is applied.

If liquids with cross-section of constant electrical conductivity are to be measured with the conductivity measuring cell according to the invention, two further cell constants are available in addition to the cell constants at the crossing points. On the one hand, this is the cell constant defined by the axially parallel lamellar electrodes 8 and, on the other hand, the cell constant formed by the parallel electrodes 10. These different cell constants avoid additional equipment and operating effort in the measurement of very different conductivities. FIG. 2 shows a conductivity measuring cell according to the invention corresponding to FIG. 1, wherein the ribs 6, 7 are shown in the installed state. The slot-shaped openings 9 of the lamellar electrodes 8 are rectangles. In a favorable variant of the invention, the leading edges 16 and the trailing edges 17 of the lamellar electrodes 8 are formed as chamfers. This counteracts to a particular extent the vortex formation in the measuring space, the gap between the electrodes 8, 10, and thus leads to exact measured values, which remain uninfluenced by the measuring cell.

The distances 11,12 of the electrodes 10 from the end faces 13 of the frame 7 are different, d. h., The electrodes 10 are arranged eccentrically in the frame 7. If the frame 7 is variable, d. H. arranged with different end faces 13 in the direction of the frame 6, arise due to the different distance of the electrodes 8,10 different cell constants. (The frame 7 is rotated about an axis perpendicular to the flow direction 3.) The distances 11,12 can now be chosen so that the resulting cell constants differ by about an order of magnitude. The measuring cell is thus adaptable to the present measuring problem.

FIG. 3 shows a conductivity measuring cell according to the invention with triangular slot-shaped openings 9 in the lamellar electrodes 8 and electrodes 10 of the second electrode system 5 designed as lamellae. The electrodes 8, 10 are located in separate frames 6, 7. The width 14 of the electrodes 8 lying in the direction of flow 3 is greater by at least a factor of 5 than the width 15 of the electrodes 10.

FIG. 3 shows the maximum possible distance 2 between the electrodes 8, 10, while FIG. 4 shows an analogous representation of the invention, but with a minimal distance 2 between the electrodes 8, 10. The eccentric arrangement of the electrodes 10 is in turn given by different Ab from 11,12 of the end faces 13. The advantage of the invention is that even at large distances 2 between the electrodes 8,10 remain laminar flow conditions or laminarization turbulent flows is achieved, so that no caused by the measuring cell mixing of the components. As a result, local electrical conductivities are determined with high measurement accuracy. The measurement accuracy is further positively influenced by the large variation possibilities of the cell constant.

Claims (5)

1. Universally applicable conductivity cell for flowing liquids, consisting of two in the flow direction successively arranged electrode systems with different surfaces, wherein the electrode systems are in a common or in separate frames, characterized in that the opposite to the flow direction (3) arranged electrode system (4) consists of axially parallel lamellar electrodes (8) with slot-shaped openings (9) pointing in the direction of flow (3) and uniformly distributed over the length, these openings (9) being associated with the electrodes (10) dps second electrode system (5), and Width (14) of the lamellar electrodes (8) is at least by a factor of 5 greater than the width (15) of the electrodes (10) of the second electrode system (5). 2. Universally applicable conductivity cell according to claim 1, characterized in that the leading edges (16) and the trailing edges (17) of the lamellar electrodes (8) ·. fluidically favorable, z. B. by attaching a chamfer are formed. 3. Universally applicable conductivity cell according to claim 1, characterized in that the electrodes (10) of the second electrode system (5) are formed as lamellae. 4. Universally applicable conductivity cell according to claim 1, characterized in that at least in the flow direction (3) lying electrode system (5) within the frame (7) is arranged eccentrically. 5. Universally applicable conductivity cell according to claim 1, characterized in that the arrangement of the frames (6,7) and thus of the electrode systems (4,5) is provided at different, preselected angles to each other.