NL8301231A - Measuring electrical conductivity of milk - by passing it through space contg. e.g. epoxy! body with two electrodes embedded in surface - Google Patents

Abstract

Method is intended for measuring the electrical conductivity of milk from a milk-producing animal whereby the milk is passed through a space (n sensors) contg. two spaced electrodes. The two electrodes are embedded in the surface of a common carrier body, which is pref. arranged such that the milk passes along the sides whilst the electrodes are positioned at different (opposite) points of its perimeter as seen in a plane normal to the main milk flow direction. The body may be arranged in an upwardly open (19) tube, at its lower end secured to this body by a transverse wall (7), the milk entering the tube parallel to the body axis, and leaving via the same open end (19).

Description

t NO 31741 - Method and device for measuring the conductivity of milk -

The applicant mentions as inventor: Hendrikus Gijsbertus Pluygers, te

Wageningen.

The invention relates to a method for measuring the electrical conductivity of the milk of lactating cattle, wherein the milk is passed through a space in which two electrodes are spaced from one another, on a device for carrying out that method , on a sensor, which forms part of that device and on a method for manufacturing such a sensor.

It is known that both clinical and subclinical mastitis infections in dairy cattle can be determined by measuring the electrical conductivity of the milk. This is described, inter alia, in M. Peaker: 10 The electrical conductivity of milk for the detection of subclinical mastitis in cows, Br. Fat. J. 154 (1978), No. 4, pp. 308/14. In devices for carrying this out, the milk flow during milking was passed through a chamber, the electrically conductive wall of which formed one of the electrodes and a rod-shaped electrode was inserted centrally in that chamber.

Such devices are expensive and difficult to manufacture, undesirable distance deviations between the electrodes are easily encountered, cavities and other surface irregularities may harbor bacteria and solids, and deposits may form on the electrodes themselves.

Attempts have been made to improve this by measuring the conductivity of the milk by electrical induction (US Pat. No. 3,762,371), but this also requires an expensive device and the measurement is highly dependent on fluctuations in the amount of milk and therefore often inaccurate.

The object of the invention is now to improve on this and to provide a cheap, reliable and accurate device and method for measuring which can be easily carried out therewith.

For this purpose, a method as referred to in the preamble according to the invention is characterized in that the milk is passed along two electrodes which are located in the surface of the same body. A device as intended according to the invention is characterized in that this device comprises a sensor with two electrodes, which are arranged at a distance from each other in the surface of the same body, with means for carrying the milk along that body.

The spacing between the electrodes is then not variable due to deviations in mounting and the parts guiding the milk along them can be simple in design, while the body with the electrodes can easily be made smooth and without dead spaces and roughness and finished.

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Preferably, the electrodes are located in the outer wall of a cylindrical sensor body projecting approximately axially in the milk flow, diametrically opposite one another and so far from the free end of that body that the distance between the electrodes along the circumference of the cylinder 5 is smaller than that measured along the surface of that body to, over and from that free end.

Such a sensor body is preferably manufactured by pouring the electrodes into an insulating casting material such as an epoxy resin and then machining the thus obtained casting into a smooth outer surface, in which the electrodes smoothly transition into the wall of the insulating casting body. .

Although such a device can measure the conductivity of the milk at any suitable location, it is recommended to place it in a milking claw of a milking machine, namely one sensor for the milk flow of each individual teat.

The invention will now be further elucidated with reference to the annexed drawings. In it is:

Fig. 1 is a somewhat schematic axial section through a milking claw of a milking installation for a cow; and Fig. 2 shows an axial section through a sensor according to the invention on a larger scale.

The milking claw 1 consists in known manner of two parts 4 and 3 screwed together by 4. The bottom part 3 has a milk discharge 5 and the cover part 2 has four milk inlet pipes 6, each originating from a teat holder of the milking cluster (not shown). Four sensors 8 are attached to a central stump 7 of the claw, e.g. glued or cast. They are substantially circular-cylindrical in shape and each stand with their axis in the axis direction of the part of one of the milk inlet conduits 6 which opens into the claw. An electrical conduit 9 of each of the two electrodes arranged therein runs through a central pipe stub 10 of the cover part 2 to an electrical circuit, not shown in more detail, but which applies an alternating electric voltage to the electrodes, e.g. of about 1 V with a frequency of 50 kHz, and measures and / or compares the resistance across the sensors. With the aid of a microprocessor, a value of the conductivity for each of the four milk flows can be determined and recorded continuously or, for example, once every 8 seconds.

The pipe stub 10 can be held by a nut 11 on the cover part 2 and easily detached therefrom.

The sensor 8 will now be described in more detail with reference to Fig. 2. A body 12 of a cast non-conductive material 8301231

V

Like an epoxy resin, it has a circular base 13 and a circular cylindrical stub 14. In that stub, two blocks 15 of stainless steel diametrically opposite each other are cast as electrodes. They are each connected to an electrical line 9. Those blocks 15 lie so far below the end face 16 of the stump 14 that the distance between those blocks along the cylinder circumference of the stump is smaller than above the end face 16.

A stepped edge 17 of the body 12 suitably accommodates the end of a tube 18, which, for example, consists of glass or a suitable plastic such as Plexiglas®, which extends above the end face 16 and has an end edge 19 in an inclined plane . That tube can be glued, glued or molded to the body 12.

For example, the stub 14 has a diameter of 6 mm and the tube an outer diameter of 12 mm.

The milk flows in a pulsating manner through each line 6 and is collected by the tube 18 of the associated sensor 8. The inner diameter of the tube 18 is preferably slightly larger (eg 2 mm larger) than the inner diameter of line 6. The milk fills that tube and rinses over the edge 19 thereof in the milking claw 1. Because the sensor 8 with its 20 open end is directed upwards, the electrodes 15 are always under the liquid during milking and thus no strongly varying signal of the liquid resistance between them is obtained, despite the pulsating milk flow.

The sensor 8 is preferably manufactured by casting the electrodes in a mold and pouring them with an epoxy resin into a somewhat larger body, which can then be brought to the desired shape and dimensions by turning or other chip-removing operation, after which the stub 14 can be ground and polished to obtain a smooth mirror surface, in which the surfaces of the electrode blocks 15 smoothly blend into the synthetic resin of that stub 14. Then no dead corners remain and no particles from the milk remain on the electrodes and the further stump.

The chamfered end face 19 of the tube 18 is chosen such that the milk finds the desired passage which is neither too wide nor too narrow, between the tube 18 and the outlet of conduit 6 in the cap 2 of the milking claw.

When the milking cluster is disconnected from the cow, the milking claw tilts on the milk discharge line 5 or on other fastening means, with which it is attached to the further milking implement, so that milk remaining in the 40 sensors runs out. The whole and also the sensors 830 1 23 1 • ~ -4- can be easily cleaned.

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Claims (15)

Method for measuring the electrical conductivity of the milk of lactating cattle, wherein the milk is passed through a space in which two electrodes are spaced from each other, characterized in that the milk is passed along two electrodes. troden, which are located in the surface of the same body. A method according to claim 1, characterized in that the milk is fed substantially all-round along and around that body, in which the electrodes are located, while the electrodes are located at different places on the circumference of that body, seen in a flat lead - 10 right on the main flow direction of the milk. 3. A method according to claim 2, characterized in that said electrode-supporting body is surrounded at a distance by a tubular body open at the top, which is connected near said lower end by a substantially closed transverse wall to said electrode-bearing body and that the milk is introduced substantially parallel to the axis of said tubular body from above between said body and the electrode-carrying body and that tubular body exits substantially through the same open end thereof. 4. Device for measuring the electrical conductivity of the milk of lactating cattle, characterized in that this device comprises a sensor with two electrodes which are arranged at a distance from each other in the surface of the same body, with means for carry milk along that body. 5. Device as claimed in claim 4, characterized in that said body is arranged in a space for guiding the milk therealong, wherein the electrodes are located at different places on the circumference of that body, viewed in a plane perpendicular to the main flow direction. of the milk. 6. Device according to claim 5, characterized in that said electrode-carrying body is surrounded at a distance by a tubular body open from above, which is connected to said electrode-carrying body near the lower end by a substantially closed transverse wall, and that the means for carrying the milk from above along that body are directed essentially along the axis of the tubular body. Device as claimed in claim 5 or 6, characterized in that the electrode-carrying body projects a cylinder, approximately axially in the milk flow, with the electrodes lying substantially diametrically opposite one another in the outer wall thereof so far from the free end of that body that the distance between the electrodes along the circumference of the cylinder is less than that distance, measured along the surface of that body to, over and from that free end. 8. Device as claimed in any of the foregoing claims 4 to 7, characterized in that it comprises more than one sensor, each contained in a separate milk flow from one teat of the udder. 9. Device as claimed in claim 8, characterized in that said sensors are accommodated in a milking claw, each for opening a conduit opening from a teat container therein. 10. Device according to claims 9 and 9, characterized in that the tubular body has a free end edge inclined on its axis. 11. Device as claimed in any of the foregoing claims 4 to 10, characterized in that the electrode-carrying body comprises a current-insulating casting in which the electrodes are cast. Device according to any one of claims 4 to 11, characterized in that the electrodes each consist of a block of stainless steel 20. Two-electrode sensor for use in a device according to any one of claims 4 to 12. 14. A sensor according to claim 13, characterized in that the surface of the electrodes and of the surrounding surface parts of the body carrying them is smoothly polished to one another. Method for manufacturing a sensor according to claim 13, characterized in that the electrodes are cast in an insulating casting material such as an epoxy resin and then the casting thus obtained is machined to a smooth outer surface, in which the electrodes with their outer surface to flow smoothly into the wall of the insulating casting body. 830 1 23 1