DE2348198A1 - FLOW METER - Google Patents

Description

The invention relates to a device for determining the volume and flow of a flowing liquid, mainly for small and variable flows, especially for monitoring the volume of urine released per unit of time of intensive care patients.

The continuous determination of a small river is more difficult and has to be solved differently than that Determination of large flows, especially if the measuring device has only a low flow resistance allowed. In such cases it has proven advantageous to divide the flow into suitable volume increments ^ V and then to measure the time that elapses until a volume increment is filled, or. the number of To determine volume increaents per unit of time. Different Devices that work on this principle are known

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For example, a device in which a container with the volume aV alternately filled and emptied via valves being, the valves from a liquid level gauge being controlled. Another device works with a tilting vessel that is held by the flowing liquid is filled and automatically when a volume £ »V is reached tilts by gravity and is emptied in the process.

These two known devices are relatively complex and have the main disadvantage that they are movable Contain parts that are subject to wear and tear. The second of the devices mentioned is also sensitive to changes in position and to vibrations, and their function also depends on the specific Weight of the liquid.

The invention is based on the object of eliminating these disadvantages.

According to the invention, this is achieved by a device of the type mentioned, which works by a siphon working on the siphon with a Container for damming the liquid flow and an emptying line connected to the container through which automatically when a certain liquid level is reached a certain volume is emptied, and a device for optical and / or electrical detection of the Fluid level and / or the drainage.

The device for detecting the liquid level can also be designed in such a way that the increase in volume is continuously measured in the container between two evacuations.

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Embodiments of the invention are described below with reference to the accompanying drawings. In the drawings demonstrate

Figure 1 is a longitudinal section through an embodiment of the invention,

Figure 2 shows a longitudinal section through another, concentric embodiment with a device for continuous Measurement of the liquid level,

Figure 3 is a schematic representation of a device for electrical measurement of the liquid level for electrically conductive liquids,

Figure 4 is a schematic representation of a device for electrical detection of the liquid level for conductive and non-conductive liquids.

The device shown in section in Figure 1 consists of a substantially cylindrical container 1, the is closed at the bottom and a tubular connector at the top for connection to the line carrying the liquid (not shown). The connector 2 forms the entrance to the device, the flow being indicated by an arrow 3 is. At one point on the cylindrical housing wall, connected in one piece with this, a U-shaped bent tube attached with two legs of unequal length 5 »6, wolaei the openings of the two legs are directed downwards. The shorter leg 5 runs concentrically to the container and empties near the bottom of the same. The longer one Leg 6 extends outside the container 1 and opens below the same; its opening forms the exit of the device, the direction of flow being indicated by arrow 7. .

On the side of the container 1 opposite the tube 4, two electrodes 8, 9 are in the wall Attached to each other at a distance to which a known per se

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Measuring device (not shown) connected for measuring an electrical current flowing between the electrodes will. In the upper side of the housing, a threaded hole is arranged next to the connector 2, into which an elongated Threaded bolt 10 is used. This bolt is used for the precise adjustment of what is encompassed by the housing 1 Volume. The volume can be increased or decreased by screwing it in or out.

The device described above is only suitable for electrically conductive liquids. The one to be measured As indicated by the arrow 3, liquid comes through the nozzle 2 into the container 1 and is dammed up there. As soon as the liquid level has reached the electrode 8, a current flows between the electrodes 8 and 9 indicates the filling process. The liquid continues to rise until it reaches the upper apex 11 of the U-shaped tube has reached. When the apex 11 of the U-shaped tube is reached, it is emptied through the leg 6 for as long Liquid until the level inside the container 1 has dropped to the level of the mouth 12 of the leg 5. As soon as the liquid level is during the emptying process has sunk below the electrode 8, the circuit between the electrodes 8 and 9 is interrupted again. After emptying, the filling starts again.

The alternating filling and emptying of the container 1 divides the liquid flow into individual volume increments AV. An electrical signal is obtained via the electrodes 8, 9 for each filling and emptying. with the help of which the number of volume increments & .V can be counted. In this way, the flow to be measured can be specified by the number of volume increments per unit of time.

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Figure 2 shows a further embodiment of the invention, in which a device for continuous measurement of the liquid level is provided and the is otherwise built concentrically. It consists of an outer substantially cylindrical housing 13 which a flange-shaped thickening 14 at its upper end. has and at its lower end with a flat bottom an opening 15 has. Are concentric in the housing 13 two interlocking inserts 16 and 19 arranged. The lower insert 16 consists essentially of a tube with a part 17 protruding upward into the interior of the housing and a part 17 protruding downward through the opening 15, the exit of the gate direction forming part 18. Inside the housing 13 has the insert 16 between the two tubular parts 17 and 18 have a circumferential thickening with a corresponding to the inner diameter of the housing 13 Outside diameter, the top of which is designed as a circumferential channel and forms the bottom of the interior of the vessel.

The upper insert 19 is also tubular in its lower part, the diameter of the tubular Partly approximately in the middle between the diameter of the housing 13 and the diameter of the tubular part 17 of the lower insert 16 is located. In this way, there remains between the housing wall 13 and the tubular part 20 of the upper insert 19 as well as between the latter and the tubular part 17 of the lower insert 16 each have an annular channel. The lengths of the tubular part 20, des upper insert 19 and the tubular part 17 of the lower insert 16 are coordinated so that the two annular channels are connected to one another and the inner annular channel is connected to the bore of the insert 16 are.

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In its upper part the insert 19 is step-shaped widened to the inside diameter of the housing 13 and finally flange-shaped by a further widening 21 educated. In this upper part, the insert 19 has a concentric recess for receiving the connection elements the electrical measuring device which will be described later.

In the flange-shaped thickening 14 of the housing there is a 90 ° angled bore 23 which with one end of its horizontal leg opens into the interior of the housing and its vertical leg follows continues at the top in a pipe socket 22, which is passed through the puddle 21 and for connection to which the liquid leading line serves. On the side opposite the bore 23 is in the flange-shaped thickening a bore is provided which connects the interior of the housing with the atmosphere in order to puncture the device guarantee.

The measuring device for measuring the liquid level in the housing 13 consists essentially of two concentrically inexnanderlxegenden capacitor plates, of one of which is formed by the housing 13 itself. For this reason, the housing 13 is either made of metal or it has a metallic coating on its inside. The second capacitor plate consists of one inside of the upper insert 19 arranged metal cylinder 24, which extends over the entire length of the tubular part 20 of the Insert 19 extends. A connector plug is in the already mentioned bore located in the upper part of the insert 19 56i for a two-wire, preferably shielded one electrical cable arranged. One contact of the plug is with the metal cylinder 24 and the other contact with the housing 13 connected.

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The function of the device "is based on the Device shown in Figure 1 based on the suction lifter principle, i.e. the liquid rises inside the housing 13, until it has reached the upper apex of the lifter 25, in order to then empty itself automatically. While the As the liquid in the container increases, the capacitance between the housing 13 and the inner metal cylinder 24 changes. This change in capacitance can be recorded, for example, by means of an electrical measuring device known per se, so that the increase in volume in the container and thus the flow between two empties can be determined. Additionally the evacuations can be counted, creating a continuous Measurement of flow and volume is made possible.

Both devices are relatively easy to manufacture. The embodiment shown in Figure 1 can be made very cheaply from two plastic shell parts. The embodiment shown in FIG. 2 can for the most part also consist of plastic. The outer housing 13 is, however, as already mentioned _; made of metal, for example aluminum.

A device for measuring the liquid level is shown schematically in FIG However, the device is only suitable for electrically conductive liquids. Inside the device is on a wall surface parallel to the device axis, an elongated electrical conductor 26 is attached, which via a line is connected to a measuring device 28 shown as a block. On a preferably opposite wall Individual electrodes 29 are arranged at intervals one above the other, which are also connected to the measuring device via lines 30 28 are connected. When the liquid level rises, successively between the electrode 26 and the individual electrodes 29 through the liquid conductive

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Connections made. The measuring device 28 can use the corresponding current signals to determine the increase in the Fluid levels are recorded gradually.

A device that is also suitable for step-by-step recording of the liquid level in the siphon vessel, which can also be used for non-conductive liquids and those to which an open electrode cannot be exposed is shown schematically in FIG. In two opposing wall parts of the device, capacitor plates are embedded, namely one on one side in the direction of the device axis and over the entire length of the maximum level difference of the liquid in the Housing extending plate 31 "and in the opposite Wall spaced apart small-area plates 33. The plate 31 and the plates 33 are each connected via lines 32 and 34 to an electronic measuring device 35 known per se. Each plate 33 forms with the plate 31 a capacitor, its capacitance changes when the gap is filled with the rising liquid and the resulting can supply the signal indicating the liquid level.

The measurement of the liquid level in the siphon container can also be done optically. To that end is the whole Vessel or opposite parts of the same made of transparent material hurriedly. One from a light source incoming light beam is directed onto the device in such a way that it is at an angle other than 90 ° hits the inner wall of the vessel. In this case the different refractive index between the liquid and the air has such an effect that the path of the The light pattern is different in the empty container than in that container filled with liquid. On the other side of the device there is then a photocell or something similar

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Light receiver arranged in such a way that the light beam For example, it encounters it when the container is full, while it passes when the container is empty. The won electrical signal can in turn be known in itself Way used to measure the liquid level or to count the empties.

Various other optical methods in which, for example, a beam of light is scattered through the liquid, attenuated or defocused can be used to determine the Fluid level or the number of times it has been emptied. In such methods, the angle of incidence of the Light beam also be 90 °.

If only one count of the empties is intended, the measuring device can also be installed on the outlet pipe 6 or to be appropriate. Because of the relatively fast Durehströniens A signal that is easy to process can be obtained from the emptied liquid at the outlet. The measuring devices correspond to the devices for electrical or optical measurement described above.

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Claims (1)

Patent claims 1. Device for determining the volume and flow of a flowing liquid, characterized by a according to the suction lifter principle working siphon with a container for damming up the liquid flow and a Drainage line connected to the container, via which automatically when a certain liquid level is reached a certain volume is emptied, and a device for optical and / or electrical detection of the Fluid level and / or drainage. 2. Device according to claim 1, characterized in that that the device for detecting the liquid level consists of two on the inside of the container wall at a distance from each other attached electrodes, which can be connected to a power source via a measuring device. 3. Device according to claim. 1, characterized in that that the device for detecting the liquid level consists of a condenser, the plates of which are to both Sides of a space periodically filled up by the liquid extend perpendicular to the liquid surface, and to which a voltage can be applied for the purpose of measurement. 4. Apparatus according to claim 1, characterized in that the device for detecting the evacuations is outside of the container is attached to the emptying line. 5. The device according to claim 1, characterized in that the device for detecting the liquid level consists of a light source and a light receiver provided with an electrical measuring device, the Light source is arranged so that its beam, under one 409818/02 9-2 of 90 ° different angle impinges on the container wall and only hits the light receiver when the container is filled with liquid or only when the container is empty. 40 9.8 18/0292