NL9500566A - Flow meter and apparatus for milking animals provided with such a meter - Google Patents

Abstract

A flow meter for determining the amount of liquid flowing through a conduit in a certain time is provided with two electrically conducting elements which are arranged at a certain distance from one another in the conduit and are connected to an electronic circuit. Based on the electrical conductivity of the liquid measured by the electronic circuit, on the magnitude of the interval during which said conductivity is measured, on the distance between the electrically conducting elements in the conduit, on the flow velocity of the liquid, and on the electrical resistivity, the amount of liquid which has flowed through in the specific time is determined in this apparatus. <IMAGE>

Description

QUANTITY METER AND ANIMAL MILKING APPARATUS PROVIDED WITH SUCH A METER

The present invention relates to a quantity meter for determining the amount of liquid flowing through a pipe in a specific time. In accordance with the invention, a simple and reliable quantity meter can be obtained when it is provided with two electrically conductive elements arranged in the pipe at a certain distance from each other and which communicate with an electronic circuit, in which electrically measured from the electronic circuit conductivity (G) of the liquid, the magnitude of the time interval (At) during which this conductivity is measured, the distance (£) between the electrically conductive elements in the pipe, the flow velocity (v) of the liquid and the specific electrical resistance (Rsw), the amount of (V) liquid that has flowed through in the given time is determined. Preferably, this electronic circuit comprises a microprocessor, in which the values of the time interval (At) and the electrical conductivity (G) measured in the electronic circuit and the values of the flow rate (v) of the liquid and the specific electrical value obtained by calibration are obtained. resistance (Rsw) the approximate amount of (V) liquid that has flowed in the given time is determined by the relation V = Rsw. £ .vG (At + £ / v). When the specific electrical resistance of the liquid is unknown or varies to some extent due to the composition of the liquid, the flow meter may be provided with a conductivity sensor incorporated in the pipe, by means of which a permanent calibration is carried out to determine the specific electrical resistance of the liquid flowing through the pipe. This conductivity sensor may comprise a liquid collecting reservoir to be incorporated in the line, in which two electrically conductive elements are arranged, which are connected to a further electronic circuit, in which, from the distance between these electrically conductive elements, the volume of the liquid in the liquid collection reservoir and the measured conductivity of the liquid, the specific electrical resistance is determined. In a special case, one of the electrically conductive elements connected to the electronic circuit may communicate with one of the electronically conductive elements of the conductivity sensor. The further electronic circuit can then be integrated in the electronic circuit, in which the amount of liquid that has flowed through during the stated time is determined. This makes it possible in a simple manner to design the quantity meter as a single unit.

The aforementioned time difference (At) can be determined by the recording in the electronic circuit of the electrical conductivity between the conductive elements at the moment that the liquid flow reaches the conducting element in the direction of flow in the flow direction and the registration in the electronic circuit of the electrical conductivity between the conductive elements when the liquid flow has passed the conductive element in the direction of flow in the flow direction and calculating the difference between these moments thereon. When the liquid stream flows through the pipe in a burst manner, the amount will be calculated in the microprocessor of each of these liquid bursts and the total amount therefrom by summing.

In a concrete embodiment, each of the electrically conductive elements is formed by a pipe piece and the two pipe pieces are kept at a certain mutual distance from each other by a further pipe piece of an electrically non-conductive material and with an internal diameter equal to that of the both electrically conductive pipe sections, while at least the pipe sections to be connected to the two pipe sections are manufactured from an electrically non-conductive material. In particular, the pipe pieces can be received in a plastic hose, while, preferably at a relatively short distance from these pipe pieces, the conductivity sensor belonging to the quantity meter is included in this hose.

In accordance with a further aspect of the invention, the quantity meter as described above can be used in a device for milking animals, such as cows. Not only will the specific electrical resistance of the milk of the different animals differ, but it may also be different in the same animal on successive milking runs, for instance because latent mastitis has occurred. This specific electrical resistance may even change in value during the milking of an animal, which is particularly the case with foremilk which generally has a lower electrical resistance than the milk flow to be obtained thereafter. Moreover, during milking, the milk flow is obtained in a pulsating manner, and this depends on the pulsation frequency with which the milking takes place.

In a first embodiment, the device for milking animals is provided with teat cups, which can be connected to the teats of the animals, and a buffer vessel, such as a milk glass, for collecting the milk obtained via the teat cups, wherein in the milk lines, by means of which the teat cups are connected to the buffer tank, a quantity meter of the above-described type is included. In this way, the amount of milk obtained from the individual udder quarters of the animal can be determined, and, if desired, the quantity of milk obtained from the udder quarter can be taken into account, when the presence of a conductivity sensor in the quantity meter determines the quantity of milk obtained from the udder quarter. changing specific electrical resistance of the milk. In a second embodiment, the device can be provided with teat cups which can be connected to the teats of the animals, a buffer vessel, such as a milk glass, for collecting the milk obtained via the teat cups, and a milk tank connected to the buffer vessel, wherein line between the buffer vessel and the milk tank a quantity meter of the type described above is included. Although in this embodiment, on the one hand, the quantities obtained per udder quarter cannot be determined separately and, because the milk is collected in a buffer vessel, no account can be taken of a specific electrical resistance of the milk which changes during milking, on the other hand, the advantage is obtained that since a separation between air and milk is effected in the buffer vessel, the total amount of milk can be accurately determined with only one quantity meter, the milk being discharged from the buffer vessel into the milk tank in a single liquid burst.

The use of a quantity meter of the above-described type in a device for milking animals is of particular importance when this device is provided with a computer and is arranged for automatic milking of the animals and furthermore is provided with a milking robot for automatic coupling and uncoupling of the teat cups to or from the teats of an animal. In that case, the electronic circuits belonging to the quantity meter can be integrated in the computer.

The invention will now be further elucidated with reference to the annexed figures, of which:

Figure 1 schematically shows a device for milking animals, and

Figure 2 shows the quantity meter according to the invention.

Figure 1 shows a milking installation 1 for a device for automatically milking an animal, for the sake of simplicity it is sufficient to represent this milking installation for only one teat cup 2. Furthermore, a buffer vessel in the form of a milk glass 3 is present. The milk collected with the aid of the teat cups 2 per udder quarter is supplied via a separate milk line 4 to the milk glass 3. From the milk glass 3, the milk is supplied to a milk tank 7 via a pump 5 via a milk discharge line 6. The milking installation further comprises as far as relevant for the present invention, a pulsator system 8 for the four teat cups 2. The vacuum line 9 for the pulsator system 8 is connected to a vacuum pump with balance tank.

The quantity meter 10 according to the invention is included in the milk line 4. Here it comprises a flow-sensitive sensor 11 for detecting the start-up and stopping of the milk flow. The sensor works on the basis of establishing an electrical connection between two electrically conducting elements (electrodes) through a milk flow. The conduit 4 is inclined downwards to prevent milk from remaining between the electrodes, in other words, from a pool of milk remaining between the electrodes; after all, this would have the effect of permanently signaling a milk flow. In the embodiment shown here, each of the electrodes is formed by a pipe piece 12, which pipe pieces are kept at a mutual distance 1 from each other by a further pipe piece 13 of an electrically non-conductive material. The internal diameter of this pipe piece 13 is the same as that of the pipe pieces 12, so that the pipe pieces 12, 13 together form one tubular body with a uniform internal diameter. The conduit 4, in which this tubular body is received, is preferably made of plastic. The two electrically conducting pipe pieces 12 are connected to an electronic circuit 14. As soon as an electrical connection is established between the pipe pieces 12 through a puddle of milk, this moment is recorded in the electronic circuit 14. When the electrical connection between the pipe pieces 12 is subsequently broken again by the further flow of the milk puddle, this moment is also recorded in the electronic circuit 14. In other words, in the electronic circuit 14 the time interval Δt is determined during which an electrical connection is present between the two pipe pieces. If the length of the milking puddle is L and the flow rate of the milking puddle V, then an electric current is detected during a time interval At = (L-1) / v. The magnitude of this current is determined by the electrical conductivity G of the milk between the two pipe pieces 12. The electronic circuit 14 is designed to determine this electrical conductivity G. For the electrical conductivity, G = A / (RBW. ), where Rsw is the specific electrical resistance of the milk and A is the cross section perpendicular to the flow direction of the milk puddle. In order to determine how much milk passes through a certain point in the line, it is necessary to take into account not only the time interval Δt, but also the time required to bridge the distance t between the pipe pieces 12. Therefore, for a time At + £ / v milk with an electrical conductivity G along a certain point through the pipe 4. For the product G. (at + £ / v) holds, with At = (L - £) / v and G = A /(RSW.V.)), that G. (At + £ / v) = AL / (RSW. £ .v.). Since the volume of the puddle of milk flowing past is equal to V s A.L, it holds that: V = RBW. £ .v.G. (At + £ / v). This relationship gives a good approximation of the amount of liquid that flows through the pipe 4 in a given time. In the electronic circuit 14, G and At are determined. Furthermore, £ is a known geometric quantity, while v and Rsw can be determined by calibration. If the flow meter were to be used for a homogeneous liquid, i.e. a liquid with a constant value of Rsw, the flow sensor 11 with the electronic circuit 14 can be used as a flow meter. At a constant value of Rsw, the value V of each puddle of liquid can simply be calculated; these must of course be summed for successive pools of liquid. With a milk flow, however, Rew varies, both in the animals to be milked successively, and even during the milking of an animal; the foremilk has a different electrical conductivity than the subsequent milk flow. Under these circumstances it is important to be able to permanently determine the value of R8W during milking. Hence, the quantity meter 10 comprises a further conductivity sensor 15 included in the line 4. The electrical conductivity of a known quantity of milk is measured continuously. In the completed embodiment, this sensor 15 is incorporated in the pipe 4 relatively close behind the sensor 14. The sensor 15 comprises a space 16 in which a known volume of milk is constantly present during milking. An electronic circuit 17 is connected to the electrodes opening into this space 16, in which the electrical conductivity of the milk in the space 16 is measured and the value of the specific resistance Rsw is permanently calculated. During the flow of the line 4, the composition of the milk can change, at least as far as the electrical conductivity is concerned, and the composition of the milk in the space 16 also changes, therefore, the electronic value 17 permanently changes the actual value. of Rsw supplied to the electronic circuit 14, so that the correct amount can be determined for each milk puddle. If desired, a mastitis sensor based on measuring the electrical conductivity can be used for the sensor 15. The electronic circuit 17 can be integrated in the circuit 14. The circuit 14 may comprise, in addition to the further electronics 18, a microprocessor 19. Furthermore, instead of a separate microprocessor 19, use can be made of the computer 20 which is present for the automatic milking system; the quantity sensor will then be part of it. The quantity meter 10 described here can be used in particular in a device for automatically milking animals, such as cows, which is provided with a milking robot 21 under control of the computer 20 for automatically coupling and uncoupling the teat cups to of the teats of an animal, respectively. In such an establishment it is important, due to the lack of permanent human control, to have a reliable quantity meter available. The amount of milk obtained from the individual quarters can be kept up to date, whereby a regular monitoring of the health status of the udder is also realized. The invention is by no means limited to the embodiment described here, but also includes all kinds of alternatives thereto, in particular those indicated in the description introduction, of course insofar as they are covered by the following claims.

Claims (16)

Quantity meter for determining the amount of liquid flowing through a pipe at a given time, characterized in that it is provided with two electrically conductive elements arranged in the pipe at a specific distance from each other and which communicate with an electronic circuit, in which: the electrical conductivity (G) of the liquid measured by the electronic circuit, - the magnitude of the time interval (At) during which this conductivity is measured, - the distance (£) between the electrically conductive elements in the line - the flow velocity (v) of the liquid, and - the specific electrical resistance (Rsw), the quantity (V) of liquid that has flowed through in the given time is determined. Quantity meter according to claim 1, characterized in that the electronic circuit comprises a microprocessor, in which the values of the time interval (At) and the electrical conductivity (G) and the values of the flow velocity obtained by calibration are measured from the electronic circuit (v) of the liquid and the specific electrical resistance (Rsw), the approximate amount of (V) liquid flowing through in the given time is determined by the relation V = Rsw. £. vG (At + £ / v). Quantity meter according to claim 1 or 2, characterized in that it is provided with a conductivity sensor incorporated in the pipe, by means of which a permanent calibration takes place to determine the specific electrical resistance (Rsw) of the liquid flowing through the pipe. Quantity meter according to claim 3, characterized in that the conductivity sensor comprises a liquid collecting reservoir to be received in the pipe, in which two electrically conductive elements are arranged, which are connected to a further electronic circuit, in which, from the distance between these electrically conductive elements, the volume of the liquid in the liquid collection reservoir and the measured conductivity of the liquid, the specific electrical resistance (Rew) is determined. Quantity meter according to claim 4, characterized in that one of the electrically conductive elements connected to the electronic circuit is in communication with one of the electrically conductive elements of the conductivity sensor. Quantity meter according to claim 4 or 5, characterized in that the further electronic circuit is integrated in the electronic circuit in which the quantity (V) of liquid flowing through in the time interval (At) is determined. Quantity meter according to any one of the preceding claims, characterized in that the time difference (At) is determined by the recording in the electronic circuit of the electrical conductivity between the conductive elements when the liquid flow reaches the conductive element in the direction of flow in the rear direction and recording in the electronic circuit the electrical conductivity between the conductive elements when the liquid flow has passed the conductive element forward in the direction of flow and calculating the difference between these moments thereon. Quantity meter according to any one of the preceding claims, characterized in that, when the liquid flow impinges through the pipe, the quantity (V) is calculated into the microprocessor of each of these liquid and the total quantity (Vtot) is summed therefrom by summing · Quantity meter according to any one of the preceding claims, characterized in that each of the electrically conductive elements is formed by a pipe section and the two pipe sections are kept at a mutual mutual distance (£) by a further pipe section of an electrically non-conductive material and having an internal diameter equal to that of the two electrically conductive pipe pieces, while at least the pipe sections to be connected to the two pipe pieces are manufactured from an electrically non-conductive material. Quantity meter according to claim 9, together with claim 3 or 4, characterized in that the pipe pieces are accommodated in a plastic hose, while, preferably at a relatively short distance from these pipe pieces, the conductivity sensor belonging to the quantity meter is in this hose included. 11. Device for milking animals, such as cows, provided with a quantity meter according to any one of the preceding claims. 12. Device as claimed in claim 11, characterized in that it is provided with teat cups which can be connected to the teats of the animals, and a buffer vessel, such as a milk glass, for collecting the milk obtained via the teat cups, wherein in the milk lines , by means of which the teat cups are connected to the buffer vessel, a quantity meter according to any one of claims 1 to 8 is included. Device as claimed in claim 11, characterized in that it is provided with teat cups which can be connected to the teats of the animals, a buffer vessel, such as a milk glass, for collecting the milk obtained via the teat cups, and one on the buffer vessel connected milk tank, wherein a quantity meter according to any one of claims 1 to 8 is included in the line between the buffer vessel and the milk tank. An implement as claimed in any one of claims 11-13, characterized in that it is provided with a computer and is arranged for automatic milking of the animals. Device as claimed in claim 14, characterized in that it is provided with a milking robot for automatic coupling and uncoupling of the teat cups to or from the teats of an animal. Device according to claim 14 or 15, characterized in that the electronic circuits belonging to the quantity meter are integrated in the computer.