DE3247722A1 - Polarographic pO2 test probe - Google Patents

Abstract

A polarographic pO2 probe having a small active surface has, over the electrolyte space, an O2-permeable membrane which encloses the surface and is screened on its inner side from the electrolyte space in an O2-diffusion-tight manner, with one or more small holes being left free. In the vicinity of the holes, a large-area cathode is mounted on the membrane. The diffusion geometry consequently becomes independent of movements of the membrane, so that the probe becomes insensitive to mechanical disturbances or pressure disturbances.

Description

Polarographic pO2 measuring probe

The invention relates to a probe as described in the preamble of the claim 1 mentioned Art.

Such probes are used to determine the oxygen content (PO2 = Oxygen partial pressure) in any media.

Such probes are of considerable importance for the determination the oxygen content in the water, for example to record basic ecological data.

Probes of the type mentioned at the beginning consume oxygen during the measuring process and therefore cause oxygen depletion in the medium, which leads to adulteration of the measured value and, in particular, makes the measured value dependent on the flow velocity of the surrounding medium. Oxygen consumption is reduced by reducing the active surface area reduced so that the probe can be made almost free of agitation.

Known probes of the type mentioned achieve this through provision very small cathode contact areas towards the electrolyte space. For example, are one or more very thin cathode wires in a (, glass body embedded and are exposed with small contact areas to the electrolyte space.

In principle, all known constructions have the arrangement in common the cathode at a distance from the membrane and a diffusion path for the oxygen, the through the membrane and the electrolyte space roughly hemispherical to the active cathode surface runs.

The disadvantage of this known construction is the strong Dependency of the probe parameters on geometic probe changes. These are however, in principle not avoidable, since the probes of the type mentioned Membrane on the more or less liquid electrolyte floats. On contact the membrane or

I) jerk fluctuations in the surrounding medium change the geometry (e.g. indentation of the membrane). This changes the geometry of the diffusion paths ("Diffusion gcometry"). For example, the diffusion paths between the medium and the active cathode surface are on average longer or the solid angle changes to diffused under the oxygen of the cathode. This results in a change the probe sensitivity and the response time.

In particular, they are noticeable when using them In the sea, probes the depth-dependent pressure influences that lead to it, for example Certain types of probes can only be used in the deep sea (high external pressure), but not can be used in shallow water (low external pressure).

The object of the present invention is therefore to provide a probe of the type mentioned to create the pressure and touch independent Measurement parameters guaranteed.

This object is achieved according to the invention with the features of the marking part of claim 1 solved.

In the construction according to the invention, the large-area cathode takes care of it Immediately after applying the preload for complete oxygen evacuation of the Electrolyte spaces. Subsequent to this extremely short running-in period is only the flow of oxygen measured through small defined holes in the otherwise oxygen-impermeable covered membrane diffused into the -Elcktrolytraum. This oxygen flow is in the immediate vicinity of the locll through the arranged there Cathode detected, so that only short diffusion distances and thus a desired high one Response speed is present.

Since the entire measuring process is in the immediate vicinity of the hole, namely above an oxygen-free and therefore not disruptive electrolyte space plays, the membrane can perform largely any movements, including the Diffusion geometry in the active measuring area remains unaffected. The membrane can in particular are bent due to contact or pressure changes over the electrolyte space, without fear of changes in the probe parameters.

A suitable choice of hole size and number of holes can be used highly sensitive but still stirring effect-free probe can be obtained.

The attached to the membrane inner surface, there for example as Layer applied cathode can consist of several electrically connected differently Sub-areas exist, of which z. 13. Areas close to the hole are connected to the measuring amplifier and other larger areas of the basic drainage serve the electrolyte space.

The probe according to the invention is advantageous due to the features of the claim 2 marked. With this construction, one is applied to the inside of the emban ivathode layer at the same time the oz-sealing of the electrolyte space. However, it must the layer on the membrane is made gas- and electrolyte-tight, this ensures that the cathode is only on its inner surface or on the Hole edge surfaces are in contact with electrolyte and only there, i.e. within the Holes is polarographically active. This is a construction that is particularly easy to manufacture and it is ensured that the probe parameters remain unaffected by external influences.

The probe according to the invention is also advantageous due to the features of claim 3 characterized. Forms above the holes when oxygen is consumed in these an approximately funnel-shaped depletion zone in the membrane.

The edge areas of this zone should be characterized by a suitable arrangement of holes If possible do not overlap or only slightly overlap, so through undisturbed training the impoverishment areas the freedom from stirring effects of the probe is guaranteed.

The probe according to the invention is also advantageous due to the features of claim 4 characterized. With such a construction, the membrane the support body surface be formed tightly, whereby the probe a high mechanical stability achieved.

The probe is advantageous due to the features of the claim 5 marked. This ensures good ventilation and distribution of the electrolyte space guaranteed on the surface.

Finally, the probe according to the invention is advantageous due to the features of claim 6 characterized. This training makes use of fact made that the large-area cathode is located in the electrolyte space and measurement location the anode arranged there is largely electrically shielded. When the cathode is grounded and a high anode lead results in excellent shielding against electrical interference.

In the drawing, the invention is exemplified and schematic shown. 1 shows a section through a first embodiment of FIG Probe according to the invention with measuring amplifier, FIG. 2 shows a section through a probe according to the invention Area probe and FIG. 3 shows a section through the membrane of an inventive A probe in an alternative design to that of FIGS. 1 and 2.

On the basis of the embodiment of FIG. 1, the basic principle can be Explain the invention as follows: An electrolyte space 1 of approximately spherical shape is surrounded by a membrane 2, which is 02-permeable, but otherwise the electrolyte space keeps away from external influences. Usually a membrane is used for this purpose made of PTFE used. On the inside of the Membrane 2 is a cathode arranged in the form of a metal layer 3. This can e.g. B. as a thin film in usual Vapor deposition, galvanic or the like. Be applied.

The cathode consists of one for polarographic oxygen determination suitable metal, such as Pt or the like.

In the illustrated embodiment, an anode 4 is a metal block formed and surrounded by an insulating ring 5 made of suitable material.

The probe configuration of FIG. 1, shown extremely schematically the membrane 2 forms approximately balloon-like over the spherical electrolyte space 1. In the balloon opening the anode 4 sits with an insulating ring 5 as a plug.

An outer clamping ring 6 seals the electrolyte space there, the insulating ring 5 providing electrical insulation between anode 4 and cathode 3 causes.

The cathode 3 is arranged firmly adhering to the inside of the membrane 2 and of such a consistency as to protect against ingress of oxygen is impermeable. According to the invention, there is a hole at any point on the membrane 7 is provided in the cathode layer 3. The electrolyte space 1 is directly in the hole in contact with the membrane 2.

Oxygen can at this point approximately in the direction of arrows 8 from the medium lying on the outside of the membrane 2 through the membrane and the hole 7 in diffuse the electrolyte space 1 and is already in the vicinity of the inner Areas of the cathode 3 converted polarographically to generate electric current.

It is made use of the fact that the cathode can only have a polarographic effect where it is in contact with the electrolyte 1. Since it is in electrolyte-tight contact with the membrane 2, this can only be its inside.

It can be seen that the diffusion geometry required for the measurement process plays a role only on the geometry of the immediate vicinity of the hole 7 is determined.

The balloon-like membrane 2 can thus be largely arbitrary be deformed without changing the diffusion geometry. It is here to take into account that in Fig. 1 the membrane thickness in relation to the diameter the overall arrangement is greatly exaggerated.

As can be seen from Fig. 1, the cathode has a polarographic active inner surface, which corresponds approximately to the total surface of the electrolyte space. When a polarographic voltage is applied to the cathode, the electrolyte space is created emptied completely from 0z very quickly.

The measuring process in the vicinity of the hole 7 remains unaffected of any oxygen conditions in the electrolyte compartment, as this is at a distance from the Hole 7 is always free of oxygen (PO2 = 0) In Fig. 1 is the electrical connection of the probe. The cathode is connected to a measuring amplifier via a line 9 10 connected, one input of which via a battery 11 is the polarography bias receives. A display instrument 12 is connected to the output of the measuring amplifier 10.

In the illustrated embodiment, the cathode is on its line 9 grounded. Because the cathode is essentially the electrolyte compartment 1 and thus encloses the entire probe arrangement in an electrically conductive manner, is an excellent one electrical shielding preserved. However, it can also be used in the usual way Anode are grounded at their connecting line 13, with the aforementioned advantage is waived.

In the embodiment of FIG. 1 of the probe can of course also several of the holes designated 7 may be provided. This increases the sensitivity the probe increased in any way.

In Fig. 2, such a probe is shown with a plurality of holes 7 '. For the sake of simplicity, the reference numerals of FIG. 1 (provided with a comma).

he mechanical structure of the probe differs from that according to Fig. 1 essentially characterized in that the electrolyte space 1 'in the form of a thin electrolyte film is formed on the reaction-neutral surface of a support body 14, the is provided for example as a glass body. In its surface are shown in Trap irregularly formed depressions are provided in which the electrolyte firmly adhering to the surface. The entire electrolyte room stands through everyone Depressions through in connection with a side next to the support body 14 arranged anode 4 '. The membrane 2 'with cathode layer 3' corresponds to the arrangement 1. However, as already mentioned, several holes 7 'are provided. To the electrical insulation between anode 4 'and cathode 3' is again an insulating body 5 'provided. The edge of the arrangement shown on the left in Fig. 2 is provided with a suitable elec- trisch insulating material 15 cast. In this way the membrane is attached to the support body 14.

Anode and cathode are in the same way, as shown in Fig. 1, Electrically connected via lines 9 'and 13'. The cathode line 9 'is grounded. The overhead anode line 13 ′ runs in a grounded shield 16.

As can be seen from Fig. 2, the holes 7 'are at a distance from one another arranged. The arrangement of holes can be irregular. However, there are those shown in Fig. 2 must be observed.

As can be seen from Fig. 2, an oxygen depletion zone is formed over each hole in the membrane 2 ', which is approximately funnel-shaped from the hole to the outer surface of the membrane is expanded. This funnel-shaped course is shown with a dashed line Lines in the section of FIG. 2 indicated.

The depletion zones shown in FIG. 2 are indicated by their dash-dotted lines Rand arbitrarily set at a certain degree of depletion, for example 1 5 pO2 drop below the ° 2 -saturated state of membrane 2 'corresponds. Should At this hole spacing, the depletion zones shown in dashed lines are in their slightly touch the outer edge areas lying on the outer surface of the membrane or overlap, the diffusion geometry is therefore only extremely slight changed so that the measurement parameters change slightly accordingly.

The layer structure of the cathode 3 or 3 'on the inside of the membrane 2 or 2 'can vary considerably will. lifle of possible Variants are shown in FIG. 3.

The membrane 2 "which is on the outside in contact with the medium 17" is coated on the inside with a cathode film 3 "with holes 7 "are designed.

The cathode film 3 ″ is, as the sectional illustration in FIG. 3 shows, however, only in the non-central area of the hole 7 ″ or in the form from there out of conductor tracks to a connection point on the embranrand. The cathode film 3 "as well as the spaces between these are marked with an 02 - impermeable neutral Film 18 covered. This covers except for openings 19 in the area of the holes 7 " the entire inner surface of the membrane 2 "including the cathode film 3", the only in the immediate vicinity of the holes 7 ″ through the openings 19 with the Electrolyte compartment 1 "is in contact.

A large cathode for oxygen depletion of the electrolyte space before the start of the feßvorganges can be provided separately.

Also to be emphasized is the possibility of using the probe according to the invention to train extremely quickly in an appealing way.

Since the diffusion resistance in the construction according to the invention is more influenced by the perforation than by the membrane thickness. the Membrane 2 can therefore be made thin, so that the probe responds very quickly.

It should also be emphasized that the probe construction according to the invention characterized by particularly favorable manufacturing options. The membrane 2, 2 ' with prefabricated cathode coating 3, 3 'can be factory-made in larger areas be made to then easy to manufacture probes to be processed. This also applies to the special design according to FIG. 3. In this way the basic problem of p02 probe production is finally solved, namely the necessity of having to work with high precision during the production process.

According to the invention, the high-precision production of the cathode film be relocated to a special company with the appropriate holes.

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Claims (6)

REQUIREMENTS: S polarographic pO2 measuring probe with a small active surface and an electrolyte space covered by an O> -permeable membrane, with which has an anode and a prestressed cathode connected to a measuring device Contact is, characterized in that the membrane inner surface (2) except for one or several small holes (7) are covered so as to be impermeable to O2 and one in the immediate vicinity Near the holes arranged cathode (3) carries, the contact surface of about the The order of magnitude of the surface area of the electrolyte space (l). 2. Probe according to claim 1, characterized in that the cathode is designed as a layer (3) which underlies the entire inner surface of the membrane (2) Leaving at least one hole (7) gas-tight and electrolyte-tight. 3. Probe according to one of the preceding claims with several holes, characterized in that the holes (7 ') have such a distance that the Oz-depletion zones created by the holes on the outer surface of the membrane do not or only overlap in negligible border areas. 4. Probe according to one of the preceding claims, characterized in that that the electrolyte (1 ') is essentially layered on the reaction-neutral Surface of a support body (14) is arranged. 5. Probe according to claim 4, characterized in that the supporting body surface is roughened. 6. Probe according to one of the preceding claims, characterized in that that the cathode (3) is grounded.