WO2012113882A2 - Flow sensor and method for detecting a flow - Google Patents

Abstract

The invention relates to a flow sensor comprising a check valve, which is arranged in a fluid line and has a valve seat and a closure element, and a magnetic field sensor. The closure element comprises a magnetic field generator or is mechanically coupled to a magnetic field generator such that a movement of the closure element relative to the valve seat results in a movement of the magnetic field generator relative to the magnetic field sensor. The magnetic field sensor is arranged so as to detect a movement of the magnetic field generator relative to the magnetic field sensor such that an output signal of the magnetic field sensor is a measure of the opening degree of the check valve.

Description

 Flow sensor and method for detecting a flow

description

The present invention is in the field of flow sensors and methods for detecting a flow, in particular those sensors and methods capable of measuring a low energy flow rate, to provide flow through conduits, for example in water-system systems, To measure, various possibilities are known. One method is the differential pressure method in which the differential pressure increases quadratically with the flow, which is why the pressure sensor used must cover a very large measuring range. Another possibility is a volumetric meter, with turbine or measuring mills being used having a relatively large slip, so that the measurement of low flow rates can not be realized. In the case of a float flow measurement, the installation position must be ensured, since a resistance body flows vertically from bottom to top. In a magnetic-inductive flow measurement, a conductive liquid flows through a time-varying magnetic field, the generation of such a magnetic field requires too much energy, so that the system can not be realized energy self-sufficient. An ultrasonic flow measurement measures the superposition of the speed of sound with the flow velocity, whereby the generation of ultrasound requires a great deal of energy. In the case of a thermal flow measurement, the thermal heaters require a very high energy requirement, so that such flow meters also require too much energy, so that corresponding systems can not be realized in an energy-autonomous manner. Optical systems used in an optical flow measurement must be permanently supplied with energy, so that they are not suitable for energy self-sufficient systems. From WO 2009/083179 AI a fluidic device is known in which a Fluidikele- ment is movably arranged in a fluid line. The fluidic element may have a throughflow opening in which a check valve is arranged. The fluidic element may at least partially consist of a magnetizable material, wherein a magnetic field sensor may be provided to conclude from a change in a measured magnetic field to a location and / or a movement of the fluidic element. The object of the present invention is to provide a flow sensor and a method for detecting a flow, which make it possible to detect a flow through a fluid path with a low energy input. This object is achieved by a flow sensor according to claim 1 and a method for detecting a flow according to claim 15.

Embodiments of the invention provide a flow sensor having the following features; a check valve disposed in a fluid conduit having a valve seat and a closure member; and a magnetic field sensor, wherein the closure member has a magnetic encoder or is mechanically coupled to a magnetic encoder so that movement of the closure member relative to the valve seat results in movement of the magnetic encoder relative to the magnetic field sensor and wherein the magnetic field sensor is arranged to move of the magnetic field sensor relative to the magnetic field sensor to detect, so that an output signal of the magnetic field sensor is a measure of the opening degree of the check valve.

Embodiments of the invention provide a method for detecting a flow, comprising the following steps:

Detecting an output signal of a magnetic field sensor arranged to detect a movement of a magnetic field transmitter relative to the magnetic field sensor, wherein a closure element of a check valve disposed in a fluid conduit comprises the magnetic field transmitter or is mechanically coupled to the magnetic field transmitter such that movement of the closure element relative to a valve seat of the check valve results in a movement of the magnetic field sensor relative to the magnetic field sensor, so that the output signal of the magnetic field sensor is a measure of the degree of opening of the check valve; and

Determining a flow through the fluid conduit based on the detected output of the magnetic field sensor. According to embodiments of the invention, the relative position of a closure member of a check valve to the valve seat of the check valve is magnetically detected by a magnetic field sensor, wherein the check valve is arranged in a fluid line, so that a leakage flow past the check valve can not take place. Thus, the present invention enables both the detection of flow rates over a large measurement ranges. Furthermore, a flow measurement is advantageously possible while simultaneously preventing a flow in a direction opposite to the flow direction of the flow to be measured. In embodiments of the invention, the magnetic field sensor can be designed as an xMR sensor, in particular a GMR sensor (GMR = giant magnetoresistive). As is known, the term xMR is a generic term for magnetoresistive effects, such as the AMR effect (AMR = anisotropic magnetoresistive), the GMR effect, the TMR effect (TMR = tunnel magnetoresistive effect), the CMR effect (FIG. CMR = co-lossal magnetoresistive) and the GME effect (GME = giant magnetic inductance). Corresponding magnetic field sensors, which have a very low power requirement, can be used according to the invention.

In embodiments of the invention, the flow sensor includes a microcontroller coupled to the magnetic field sensor and configured to receive the output of the magnetic field sensor and determine a flow rate based thereon. The microcontroller may be further configured to output, for example, display a flow rate indicative signal or to transmit wirelessly or by wire to a receiver. The microcontroller may be configured in embodiments of the invention to switch the magnetic seed sensor between a measurement phase and a quiescent phase with a predetermined duty cycle, and energy consumption can be further reduced by appropriately adjusting the duty cycle. In embodiments of the invention, a magnetic field switch is further provided whose task is to wake the system comprising the MikrocontroUer and the magnetic field sensor. Thus, the system is only active when needed, so that the energy consumption can be further reduced. The magnetic field switch may be implemented, for example, as a GMR magnetic field switch.

In embodiments of the invention, the magnetic field switch itself can take over the function of a magnetic field sensor which can detect a fixed threshold so that the flow sensor acts as a threshold switch. Embodiments of the present invention thus make it possible to detect a flow in a fluid conduit, for example a water flow in a water conduit, with a very low energy requirement, whereby both small dripping quantities and large flow rates can be detected and measured. According to the invention, it is not necessary to use different types of sensors in order to measure both small dripping volumes and high flow rates of several liters per minute, as is the case with current systems. In current systems, this is necessary because the individual sensor types usually cover only a small measuring range with the required accuracy. In addition, conventional flow sensors typically use physical principles to measure a flow, such as a flow of water, associated with a high energy demand. The present invention provides flow sensors and methods for detecting flow that have lower energy consumption, less slippage, and a wider range of measurement. Thus, embodiments of the present invention are suitable for applications for which known systems are excluded due to the mentioned disadvantages. Thus, embodiments of the invention are suitable for sensors that are capable of detecting and measuring the water flow in water lines with extremely low energy consumption, so that the use of battery-operated measuring and control systems becomes possible. The use of energy harvesting to supply power to monitoring systems (such as condition monitoring systems) is also made possible for the first time by the use of such systems.

Exemplary embodiments of the present application are explained in more detail below with reference to the accompanying drawings. Show it:

a schematic representation of an embodiment of a flow sensor according to the invention;

Fig. 2a) to 2c) are schematic representations showing an embodiment of a flow sensor according to the invention in various states;

Fig. 3 is a schematic representation of an alternative embodiment of a flow sensor according to the invention;

4a, 4b are schematic representations for explaining a further embodiment of a flow sensor according to the invention; and Fig. 5 is a schematic illustration for explaining a magnetic switch. Fig. 1 shows an embodiment of the invention, in which a check valve 10 is installed in a fluid line 12, for example, a water pipe. The check valve has a valve seat 14 in the form of a sealing ring. The sealing ring is attached to suitable attachment means in 16 in the fluid conduit 12. The check valve 10 also has a closing cone 1 8, which is resiliently mounted against the valve seat 14, as indicated in Fig. 1 by a spring 20. The closing cone 18 has a magnetic field transmitter 22, as shown schematically in FIG. For this purpose, the closing cone 1 8 either consist of a magnetic material or a magnet may be attached to the closing cone. The magnetic encoder 22 generates a magnetic field 24, as shown by corresponding field lines in FIG.

The check valve 10 is configured to allow fluid flow only in a direction shown by an arrow 26 in FIG. 1. A fluid flow in the direction of the arrow 26 generates a force acting on the closing cone 1 8 force, so that the closing cone 1 8 lifted from the valve seat 14 and the valve is opened. The degree of opening of the valve depends on the flow rate, ie on the flow rate.

In a suitable position relative to the check valve 10 and thus to the magnetic encoder 22, a magnetic field sensor 28 is arranged. The magnetic field sensor 28 is arranged at such a position relative to the check valve 10 that its output signal depends on the position of the closing cone 18, which in turn depends on the flow rate of the fluid flowing through the fluid line. This dependence is indicated in a diagram 30 in FIG. 1, which represents the output voltage U of the magnetic field sensor 28 over time t. In embodiments of the invention, the magnetic field sensor is formed by a GMR sensor.

The magnetic field sensor is thus arranged relative to the closing cone 18 and thus the magnetic field transmitter 22, that a movement of the closing cone 18 and thus the magnetic encoder 22 leads to a change of the output signal of the magnetic field sensor, so that the output signal of the magnetic field sensor is a measure of the degree of opening of Check valve is. By calibrating the system can thus be deduced directly by the output signal of the magnetic field sensor 28 to the flow rate through the check valve. Figures 2a) -2c) show the output signal of the Magnetfeidsensors 28 for different degrees of opening of the check valve. According to Fig. 2a) no flow takes place, so that the check valve 10 is closed. The magnetic field sensor 28 is thus exposed to only a small part of the magnetic field generated by the magnetic encoder 22, so that the output signal of the magnetic field sensor 28 is at a low level, as indicated by the low output voltage in the diagram 30a in Fig. 2a). According to Fig. 2b), a first low flow through the conduit 12 takes place, so that the check valve 10 is slightly open. The magnetic field transmitter 22 is moved by the deflection of the check valve 1 8 to the magnetic field sensor 28, so that the output signal thereof has a higher level, see diagram 30b. According to Fig. 2c) finally, a second high flow takes place, so that the magnetic encoder was moved by the deflection of the check valve 1 8 even closer to the magnetic field sensor 28, so that it is the generated magnetic field 24 more exposed. The output of the magnetic field sensor 28 has a correspondingly higher level, as shown in diagram 30c.

Since the demand for a magnetic field sensor, and in particular of an xMR sensor, for example of a GMR sensor, is very low, a corresponding flow sensor can be operated with a very low energy requirement. For example, the power requirements of conventional GMR sensors can be around 9 mW. Thus, corresponding embodiments of the invention enable flow detection with a low energy requirement.

3 shows a schematic cross-sectional view of an alternative embodiment of the invention designed to enhance the measurement effect. 3 shows a flow sensor arrangement with a first connecting piece 32, a second connecting piece 34 and a fluid channel connecting the connecting pieces. The fluid channel is indicated in Fig. 3 by a line 36. In the fluid channel, a check valve 40 is arranged, which has a valve seat 42 and a closure element in the form of a ball 44. The ball 44 may be biased against the valve seat 42 by gravitational force. The ball 44 is attached to a lever arm 46 to which a magnetic encoder 48, for example in the form of a magnet, is also attached. The lever arm 46 is clamped at the end to which the ball 44 is mounted while the magnetic encoder 48 is mounted at the other end thereof. If a fluid flow then takes place through the fluid conduit 36, the ball 44 is moved upward in the direction of the arrow 50. This movement is translated by the lever arm 46 into a larger movement of the magnet 48, as shown by an arrow 52 in FIG. Thus, the deflection of the magnetic encoder 48 according to the law of leverage corresponds to a multiple of the movement of the ball. This increased according to the length of the lever deflection can be detected by a magnetic field sensor 54 which is opposite to the magnetic encoder 48.

In embodiments of the invention can thus be effected by providing a lever, an enlarged deflection of parts of a flow element, said increased deflection can be detected by a magnetic field sensor, so that the measurement accuracy can be increased.

As stated above, magnetic field sensors and in particular GMR sensors have a very low energy requirement. In embodiments of the invention, a microcontroller is provided that is configured to return to flow through the fluid conduit based on the output of the magnetic field sensor. The microcontroller may be programmed to access, based on the output signal of the magnetic field sensor, a look-up table in which flow rates associated with different output signals are stored, the data of the lookup table being obtainable by calibration of the system. The microcontroller may be configured to operate the magnetic field sensor with a duty cycle that describes the ratio between the active phase of the magnetic field sensor and the idle phase thereof. In the active phase, the magnetic field sensor is powered and provides output signals, while it is not powered in the resting phase and thus consumes no energy. The duty cycle may be suitably chosen to provide a trade-off between the behavior of the flow sensor and its power consumption. In embodiments of the invention, the output of the magnetic field sensor is evaluated by means of a microcontroller, which may be configured to access a look-up table based on the output of the magnetic field sensor based on calibration data. The look-up table can also take into account further parameters which may have an influence on the measured flow, for example the temperature present during the measurement. For detecting these further parameters, additional sensors, for example a temperature sensor, may be provided. The lookup nozzles may be calibrated for a particular fluid whose flow is to be measured, for example, water. Alternatively, the look-up table may contain data for multiple fluids, with a possibility to select between the fluids.

In order to further reduce energy consumption, in embodiments of the invention, an additional magnetic field switch may be provided by which the system only then aroused when a flow through the fluid line takes place. The magnetic field switch may be implemented by a GMR switch, for example, where the power requirements of typical GMR switches may be 400 nW. The magnetic field switch, as well as the magnetic field sensor, mounted on a position where he can observe the movement of the check valve, ie, where he can observe the relative movement between the closure element and the valve seat.

An exemplary embodiment of a flow sensor according to the invention, in which a sensor unit 100 has a magnetic field switch 102, a magnetic field sensor 104 and a microcontactor 106, is shown in FIGS. 4a and 4b. The microcontroller is electrically coupled to the magnetic field switch 102 and the magnetic field sensor 104, as indicated by arrows 108 in FIG. 4a.

In Fig. 4a, the check valve 1 0 is shown in a closed state, in this state, the magnetic field sensor 1 04 and the microcontroller 1 06 are in a sleep mode. A sleep mode of a magnetic field sensor is to be understood as meaning a mode in which the magnetic field sensor is not supplied with energy and thus does not consume any energy. Sleep mode of the microcontroller is a mode in which the power consumption of the microcontroller is reduced compared to an active mode by turning off components of the microcontroller, ie. H. not be energized. For example, during sleep mode of the microcontroller, only one timer may be active. Such sleep modes of microcontrollers are known, wherein microcontroller can be woken up, for example by a Signaiii ske at an interrupt input from the sleep mode. In embodiments of the invention, an interrupt input of the microcontroller 106 can thus be connected to an output of the magnetic field switch 102, so that the microcontroller can be awakened from the sleep mode into the active mode by a signal edge in the output signal of the magnetic field switch 102. The microcontroller is configured to activate the magnetic field sensor after placing it in the active mode to measure the flow through the line 1 2.

Thus, the microcontroller 1 06 and the magnetic field sensor 1 04 are in the closed state of the .Rückschlagventils 1 10 shown in Fig. 4a in sleep mode in which the magnetic field sensor can be completely disabled. The magnetic switch 102 is active and monitors the position of the valve. As the valve moves, this movement is detected by the magnetic switch 102. More specifically, the magnetic field switch 102 detects a change in the magnetic field caused by a movement of the magnetic field sensor 22 and switches when the magnetic field caused by the magnetic encoder 22 netfeld assumes or exceeds a predetermined value. As a result, a signal edge is generated in the output signal of the magnetic switch 22, which starts the microcontroller 1 06 via an interrupt. As a result, the microcontroller 1 06 is put into an active mode and in turn activates the magnetic field sensor 1 04. This results in the scenario shown in Fig. 4b, in which the microcontroller 1 06 and the magnetic field sensor 104 are active. In this state, the magnetic field sensor carries out measurements in order to determine the exact position of the valve, in particular of the closure element 18. In this respect, the functionality of the magnetic field sensor corresponds to the functionality described above with reference to FIGS. 1 and 2. With the aid of the information about the position of the closure element and thus the degree of opening of the valve, the flow rate can be determined, for example by calculation or by accessing a look-up table.

When the valve closes again, this can be detected based on the output of the magnetic field sensor 104. Thereafter, the microcontroller 1 06 and the magnetic field sensor 104 can be put back into sleep mode. In embodiments of the invention, the magnetic field switch can be placed in a sleep mode in which it is not energized when the microcontroller and the magnetic field sensor are in the active mode. In such embodiments, the magnetic field switch is again put in an active mode when the microcontroller and the magnetic field sensor are put into sleep mode.

In embodiments of the invention, the microcontroller can also be put into sleep mode by a further edge in the output signal of the magnetic switch 102 from the active mode, wherein such a signal edge can be generated in the output signal of the magnetic switch 102, if caused by the magnetic encoder Magnetic field again assumes the predetermined value or crosses.

In embodiments of the invention, a further magnetic field switch may be provided which is configured to generate in an output thereof a digital signal handler when the magnetic field caused by the magnetic transmitter assumes a second predetermined value. The second predetermined value may for example be associated with a specific opening position of the valve, for example an opening end position of the valve. The further magnetic field switch can be coupled to the microcontroller 1, in such a way that the microcontroller is put into sleep mode when the signal edge occurs in the output signal of the second magnetic field switch. Thus, embodiments of the present invention enable setting of a defined measurement range. In embodiments of the invention, the switching threshold of the magnetic switch can be set so that, while the check valve is closed, the threshold is not exceeded. Once a fluid flow, such as a water flow, begins, the check valve moves and the digital output of the magnetic switch changes from one binary value to another, for example from 0 to 1 or vice versa. This edge change is used to wake up and activate the microcontroller and thus also the magnetic field sensor with the aid of an interrupt. The magnetic field sensor begins to accurately measure the position of the valve and once the measurement is completed, the magnetic field sensor and the microcontroller are put back into sleep mode. The magnetic field sensor only needs energy when a fluid flow really takes place. In the time when no flow takes place, the magnetic field sensor is completely inactive. In embodiments, the switching threshold can be set so that the system is activated only when a threshold, which represents the lower limit of a certain measuring range is reached. As stated above, to limit the measuring range upwards, another magnetic field sensor can be used. In embodiments of the invention, a magnetic field switch itself act as a magnetic field sensor, wherein the magnetic field switch takes over the task of detecting a predetermined threshold. With such a construction threshold levelers can be realized, which switch from a previously set amount of flow. An additional magnetic field sensor which makes an accurate qualitative measurement of the magnetic field is not provided in such embodiments.

A functional block diagram of a magnetic field switch as may be used in embodiments of the present invention is shown in FIG. The magnetic field switch comprises an oscillator and timer 1 10, a sensor element 1 12, a Kornparator 1 14, a latch 1 16 and a switch 1 18, for example in the form of a field effect transistor. The output of the oscillator and timer 110 is coupled to the sensor element 12 and the comparator 14 to apply a suitable measurement cycle, as indicated by pulses 120 in FIG. Furthermore, a supply voltage V _{DD is} shown in FIG. The sensor element 1 12 may be formed, for example, as a Wheatstone bridge, wherein the output signal of the comparator 26 depending on the magnetic field detected by the sensor element 1 12 has a high or low level. The output of the comparator 1 14 is coupled to an input of the latch 1 1 6, whose output is in turn coupled to a control terminal of the switch 1 1 8. Dependent from the output of the latch 1 16, the switch 18 leaves an output 122 of the magnetic switch 102 at a high logic level or pulls it to a low logic level. At the output 122 thus a digital output signal is output, which can assume a logic high or logic low level.

In embodiments of the invention, the magnetic field switch can be designed as a GMR magnetic field switch by the sensor element 1 12 is designed as a GMR sensor element. With such magnetic field switches, no offset correction is necessary because the magnetoresistive material used in the GMR sensor element does not magnetize irreversibly. Examples of such a sensor draw in the operating mode on average only a current of about 0, 1 2 μΑ.

Embodiments of the present invention have been described above with reference to a check valve in which a closing cone or ball releases or closes a valve opening formed by a valve seat. Alternative embodiments of the invention may use other check valves, for example

Flap valves or the like, as long as the movable closure member is mechanically coupled to a magnetic encoder that a movement of the Verschlussclements is converted into a movement of the magnetic encoder, so that a position of the closure member relative to the valve seat can be detected by a corresponding magnetic field sensor.

In embodiments of the invention, the magnetic encoder can be formed by a permanent magnet. In alternative embodiments, the magnetic field encoder can consist of a magnetizable material, so that an external, for example, by an external permanent magnet, generated magnetic field can be changed by the magnetic encoder, this change is in turn detected by the magnetic field sensor. Embodiments of the invention thus relate to a flow sensor in which a passage valve is arranged in a fluid line such that no flow can take place past the check valve. Embodiments of the present invention further relate to corresponding methods for detecting flow through a fluid conduit that are executable by corresponding flow sensors.

Embodiments of the present invention thus enable the realization of a sensor for flow detection, which were not possible with previous technologies, in particular the implementation of self-powered or battery-powered systems. For example, embodiments of the invention may be used to implement

Water monitors are used in which energy is generated with the aid of a turbine generator itself, so that the system must work with very little energy, so that no commercially available sensors for flow detection can be used. Embodiment embodiments of the invention make it possible to detect both very small flow quantities in the drop zone and very large flows of several liters per minute. Possible uses for embodiments of the invention include measurement and control of the flow and / or detection of leakage in lines of water consumers, such as e.g. Irrigation systems, washing machines, dishwashers, vending machines, water dispensers, coffee machines and the like.

Claims

claims A flow sensor comprising: a check valve (10) disposed in a fluid conduit (12) having a valve seat (14; 42) and a closure member (18; 44) and a magnetic field sensor (28; 54; 104), the closure member (18; 44) has a magnetic field transmitter (22) or is mechanically coupled to a magnetic field transmitter (48) such that movement of the shutter member (18; 44) relative to the valve seat (14, 42) moves the magnetic field transmitter (22; 48) relative to The magnetic field sensor (28; 54; 104) is arranged to detect a movement of the magnetic field transmitter (22; 48) relative to the magnetic field sensor (28; 54; 104) such that an output signal of the magnetic field sensor (28; 54; 104) is a measure of the degree of opening of the check valve, Flow sensor according to claim 1, wherein the valve seat (14; 42) is fixedly attached to the Fluidlcitung. Flow sensor according to one of the preceding claims, in which the magnetic field sensor (28; 54; 104) is an xMR sensor, in particular a GMR sensor, A flow sensor according to any one of claims 1 to 3, further comprising a microcontroller (106) coupled to the magnetic field sensor (28; 54; 104) and configured to control the output signal. receive the magnetic field sensor (28; 54; 104) and determine a flow rate based thereon. Flow sensor according to claim 4, wherein the microcontroller (1 06) is designed to determine the flow rate based on stored in a lookup table calibration data. The flow sensor of claim 5, further comprising a magnetic switch (102) disposed relative to the magnetic encoder (22; 48) and configured to generate a digital signal edge in an output thereof when the magnetic field caused by the magnetic transmitter (22; 48) is predetermined Value, wherein the microcontroller (106) is coupled to the magnetic field switch (102) and configured to be awakened from a sleep mode and put into an active mode in response to the digital signal edge. The flow sensor of claim 6, wherein the microcontroller (106) is configured to activate the magnetic field sensor (104) when placed in the active mode. The flow sensor of claim 6 or 7, wherein the microcontroller (106) is configured to be put back into sleep mode upon detection of the flow rate upon receipt of the output of the magnetic field sensor (104) or after a predetermined period of time. 9. A flow sensor according to claim 6 or 7, wherein the microcontroller is configured to be set in the sleep mode when the output of the magnetic field sensor (104) indicates that the magnetic field generated by the magnetic encoder assumes a predetermined value or crossed. The flow sensor of claim 8 or 9, wherein the microcontroller (106) is configured to disable the magnetic field sensor (104) when placed in sleep mode. 1 1. A flux sensor according to any one of claims 6 to 10, comprising a further magnetic field switch disposed relative to the magnetic field transmitter (22; 48) and configured to generate a digital signal edge in an output thereof when the magnetic field emitter (22 48) accepts or traverses a second predetermined value, wherein the microcontroller (1 06) is coupled to the further magnetic field switch and configured to be placed in sleep mode in response to the digital signal edge in the output signal of the further magnetic field switch such that the predetermined value and the second predetermined value define a measuring range. The flow sensor of claim 4, wherein the microcontroller is configured to switch the magnetic field sensor (28; 54) between a measurement phase and a quiescent phase at a predetermined duty cycle. Flow sensor according to one of the preceding claims, wherein the magnetic field sensor comprises a magnetic field switch, in particular a GMR switch, which is designed to switch and output a digital signal edge when the closure element assumes or traverses a predetermined position. Flow sensor according to one of the preceding claims, wherein the closure element comprises a lever (46) which is arranged between a closure portion (44) of the closure element and the magnetic field transmitter (48), wherein the lever (46) is adapted to a movement of the Closing section (44) in a movement of the magnetic field transmitter (48), which is greater than the movement of the closure portion (44),, method for detecting a flow, comprising the following steps: Detecting an output signal of a magnetic field sensor (28; 54; 104) arranged to sense a movement of a magnetic field transmitter (22; 48) relative to the magnetic field sensor, wherein a shutter member (18; 44) of one in a fluid conduit (1 2 The magnetic field transmitter (22) or is mechanically coupled to the magnetic field transmitter (48), so that a movement of the closure element (1 8, 44) relative to a valve seat (14, 42) of the check valve ( 10, 40) results in a movement of the magnetic field transmitter (22; 48) relative to the magnetic field sensor (28; 54; 104) such that the output of the magnetic field sensor is a measure of the degree of opening of the check valve (10; 40); and Determining a flow through the fluid line (12) based on the detected output of the magnetic field sensor.