奥地利专利AT512504A4 Apparatus and method for determining the capacity

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专利摘要:
The invention relates to a device for determining the capacitance between two electrodes (4, 5) comprising a measuring circuit (6) connected downstream of the electrodes (4, 5) for determining the capacitance between the two electrodes (4, 5), one of the measuring circuit (6 ) connected downstream communication unit (7), as well as to the communication unit (7) connected first antenna (8) with coil-shaped structure and with at least one winding, wherein the communication unit (7) for transmitting the measured values to an external data communication unit (40) is formed , According to the invention, the device comprises a second antenna (9) with coil-shaped construction and with at least one turn which is connected to the measuring circuit (6), wherein the terminals of the second antenna (9) connected directly or indirectly to the electrodes (4, 5) are such that upon excitation of the antenna (9) with an alternating electromagnetic field, an AC voltage applied to the electrodes (4, 5). According to the invention, it is further provided that the measuring circuit (6) is designed for the direct or indirect measurement of the alternating voltage applied to the electrodes (4, 5) or the alternating current flowing through the electrodes (4, 5) and that the output of the measuring circuit is direct or indirect the communication unit (7) is supplied.
公开号:AT512504A4
申请号:T358/2012
申请日:2012-03-22
公开日:2013-09-15
发明作者:Manfred Dipl Ing Bammer；Gernot Dipl Ing Schmid
申请人:Seibersdorf Labor Gmbh；Ait Austrian Insitute Of Technology Gmbh；
IPC主号:

专利说明:

1
The invention relates to a device for determining the capacitance between two electrodes according to the preamble of the independent patent claim 1 and to a device for determining the capacitance according to the preamble of the independent patent claim 12.
From the prior art a variety of devices for the administration of fluids is known. Such devices are primarily used in the field of administering medicaments to persons or animals. In particular, the administration of insulin to diabetics or applications in which the dosage of drugs, hormones, biologicals, etc. is an important factor is a preferred field of application for devices according to the invention.
Delivery devices for delivering insulin in the form of a liquid to diabetics known as "insulin pens" are known in the art. With such devices, insulin in the form of a liquid of the required amount can be easily and safely administered to the respective patient, the patient can control the administration himself. In principle, the administration devices each have an ampoule with the respective gaseous or liquid medicament, here insulin. These ampoules are often referred to as cartridges. The cartridges are loaded into the delivery device with an injection mechanism removing the drug from the respective cartridge and delivering it to the patient.
The injection mechanism is further provided with a metering mechanism which delivers a certain amount of the respective drug to the patient. The problem here is that the dosage may not work properly if the required amount of drug is not present in the respective cartridge or ampoule. Although most of the products on the market can be read via a viewing window the respective level of the cartridge or ampoule, but this only allows an approximate determination of the residual insulin content or the residual liquid content in the cartridge or ampoule. Reading through the viewing window provides in most cases only a very rough reading. Patients with impaired vision may find it difficult or impossible to reliably determine residual insulin content or residual fluid content. Another problem that opens up in many applications is the remembering of the last fill level or the injected amount of the last injection. This not only affects forgetful people and can lead to under- or overdose. • «• 9 • · · · ι
To remedy the first problem, the principle of capacitive level measurement is known from the prior art. For this purpose, at least two electrodes are mounted either on the ampoule or cartridge itself or on the inside of the lower pen shaft in the region of the ampoule. The attachment of the electrodes can be carried out, for example, by vapor deposition or gluing, wherein in the case of gluing or vapor deposition on the inside of the pen shaft, the ampoule inserted into the pen should rest closely against the inside of the pen shaft. Due to the significantly different dielectric properties of the liquid, in particular of insulin, and the dielectric properties of the non-metallic materials surrounding the liquid, the capacitance Cm measured by the two electrodes is dependent on the filling level in the ampoule. The ampoule or cartridge is referred to in the context of the present invention as a liquid container.
In Fig. 1 to 3, the underlying principle of the determination of the remaining amount of liquid L in a liquid container 1 is shown in more detail. Fig. 1 shows a liquid container 1 in the form of an ampoule, on the outer wall of which metal electrodes 4, 5 are glued or vapor-deposited, from the side. Fig. 2 shows the liquid container 1 from above. The metal electrodes 4, 5 are circumferentially separated
Portions of the outer shell of the cylindrical container 1 and do not touch each other. 3 shows the relationship between the capacitance measurable between the metal electrodes as a function of the fill level of the liquid container 1 at different fill levels and with different sizes of the electrodes 4, 5. By measuring the capacitance between the two electrodes 4, 5 of the liquid container 1 can readily be closed to the level L of the liquid container 1 with the respective liquid 14, for example a drug, provided that the permittivity of the liquid 14 from the permittivity of air or otherwise instead of the liquid 14 into the liquid container 1 penetrating fluid sufficiently different. In the present case, the ratio of the two permittivities is about 1:80.
A problem with the capacitive level determination method illustrated in FIGS. 1 to 3 is that this embodiment requires an alternating voltage source for determining the capacitance, in particular for components which are connected to an NFC-compatible mobile phone or to another with NFC
Interface equipped data communication device to be operated completely passive, leading to problems. In particular, it is extremely expensive to integrate a battery for generating an alternating voltage for determining the capacity.
The object of the invention is therefore to provide a device which allows the measurement of the capacitance of a capacitor in a, in particular NFC-compatible, passive component without a separate power supply is required.
The invention solves this problem in a device of the type mentioned above with the characterizing features of claim 1. According to the invention in a device for determining the capacitance between two electrodes comprising - a downstream of the electrodes measuring circuit for determining the capacitance between the two electrodes, - a the communication circuit downstream of the measuring unit, and - a connected to the communication unit first antenna coil-shaped structure and at least one turn, wherein the communication unit is designed to transmit the measured values to an external data communication unit, provided: - a second antenna with coil-like structure and with at least one winding, which is connected to the measuring circuit, wherein the terminals of the second antenna are connected directly or indirectly to the electrodes, so that upon excitation of the antenna with an electromagnetic An alternating voltage is applied to the electrodes in the alternating field, wherein the measuring circuit is designed for the direct or indirect measurement of the alternating voltage applied to the electrodes or the alternating current flowing through the electrodes, and the output of the measuring circuit is fed directly or indirectly to the communication unit.
In a device according to the invention has the significant advantage that a measurement of the capacity without a separate AC voltage generator and without a battery or an accumulator is possible and the device of the invention operates completely passive. This also has the advantage that there is practically no measurable heating of the liquid in the ampoule, which may be critical for many temperature-sensitive injection solutions.
A particularly simple measurement of the capacitance provides that in each case one of the terminals of the second antenna is connected to one of the two electrodes,
I • ·:
A that the measuring circuit is designed to determine the amplitude of the voltage between the two electrodes and at its output holds a measured value corresponding to this amplitude available.
In order to determine measured variables and capacitances, irrespective of the respective position and orientation of the communication device, it is advantageously provided that a third antenna with coil-shaped construction and with at least one winding, which wraps around the same area as the second antenna, and in particular has the same number of turns as the one second antenna, a reference capacitor having a predetermined capacitance, wherein the terminals of the third antenna are connected directly or indirectly to the electrodes of the reference capacitor, so that upon excitation of the third antenna with an alternating electromagnetic field an AC voltage applied to the electrodes of the reference capacitor, a second measuring circuit for indirect or direct measurement of the AC voltage applied to the reference capacitor or of the alternating current flowing through the reference capacitor and a capacitance and / or Meßwertbest upstream of the communication unit which determines the ratio of the measured values ascertained by the measuring circuits, in particular subjects them to a calibration function and / or converts them into a measured value derived from the capacitance, and outputs them at their output, wherein the communication unit transmits this ratio as a respective measured value for the quantity of the Liquid container remaining liquid is formed.
A particularly simple measurement of the reference capacitance provides that in each case one of the terminals of the third antenna is connected to one of the two electrodes of the reference capacitor, and that a second measuring circuit which is designed to determine the amplitude of the voltage between the terminals of the reference capacitor and the reference capacitor is connected downstream, wherein the communication unit has a further input which is connected to the output of the second measuring circuit
An embodiment of the invention that is simple to train, robust and reliable in terms of determination provides that the second antenna and the third antenna, if appropriate also the antenna, wrap around the same area.
An advantageous development of the invention can be used to determine the liquid content in a liquid container. Here is a 3
I 3 I * * * * * * * * *
Liquid container provided at the, in particular inner or outer, surface, the two electrodes are arranged opposite each other and not touching, wherein preferably the capacitance between the two electrodes depends on the amount of liquid in the liquid container and wherein the output from the measuring circuit measured value of the amount corresponds to the liquid contained in the liquid container.
For administering the liquid to a living being, it may be provided that the liquid container is in fluid communication with an administration means which is preferably designed for injection of this liquid to a living being.
For correct metering of the liquid to be administered, it may be provided that the administering means is controlled by a control unit, which is supplied with the measured value for the level of the liquid container, wherein the control unit activates the administering means until the level of the liquid container is reduced by a predetermined amount is.
Furthermore, the invention relates to an arrangement with a device according to the invention and a data communication unit, wherein the data communication unit for emitting electromagnetic waves to the first antenna, the second antenna and optionally to the third antenna is formed. Advantageously, the data communication unit is implemented by a mobile telephone. With this arrangement, the capacity can be determined advantageously and without arranged in the device energy source.
For the advantageous registration and processing of the measured data, it can be provided that the data communication unit has a receiving unit for receiving the measured values output by the device and a memory for storing these measured values.
For controlling the dispensing of liquids, it may be provided that the data communication unit has a further control unit which receives the measured value for the level of the liquid container at predetermined time intervals, determines the difference between the level and a fill level stored in its memory and emits a signal, if this difference exceeds a predetermined threshold.
The invention further relates to a method for determining the capacitance between two electrodes having a first antenna for data communication and a second antenna having a coil-shaped structure and having at least one winding which is connected directly or indirectly to the two electrodes, so that upon excitation of the antenna with a alternating electromagnetic field an AC voltage applied to the electrodes. According to the invention, the second antenna is excited by a data communication device with an alternating electromagnetic field and thus an alternating voltage is applied to the electrodes, and that the capacitance between the two electrodes is determined with the aid of the alternating voltage, and the capacitance or a value derived therefrom the first antenna is transmitted to the data communication device.
In the method according to the invention, there is the advantage that a measurement of the capacitance without a separate AC voltage generator and without a battery or an accumulator is possible and the device according to the invention operates completely passively. This also has the advantage that there is virtually no measurable heating of the liquid in the vial, which may be critical for many temperature sensitive injection solutions.
In order to determine measured variables and capacitances independently of the respective position and orientation of the communication device, a third antenna is advantageously provided, which in particular wraps around the same area as the second antenna, and a reference capacitor with a predetermined capacitance, wherein the terminals of the third antenna directly or indirectly the electrodes of the reference capacitor are connected, so that upon excitation of the third antenna with an alternating electromagnetic field an AC voltage applied to the electrodes of the reference capacitor, wherein the third antenna is excited by the data communication device together with the second antenna with an alternating electromagnetic field, whereby the reference capacitor an AC voltage is applied, and that with the aid of the AC voltage, the capacitance of the reference capacitor is determined, and the ratio between the capacitance between the two electrodes and the Reference capacitor is transmitted to the data communication device.
An advantageous development of the invention can be used to determine the liquid content in a liquid container. Here, a liquid container is provided, on whose, in particular inner or outer, surface, the two electrodes are opposite and not touching each other. Are arranged, characterized in that the capacitance between the two electrodes or the ratio between the capacitance between the two electrodes and the reference capacitor as a measure of the level considered is and is converted, in particular according to a calibration table, in a level.
In order to be able to interrogate and monitor the individual dosages, it can be provided that the fill level of the liquid container is transmitted to the data communication unit and that the transferred fill level is stored in the data communication unit or another data communication device connected to it and can be retrieved later is.
For correct metering of the liquid to be administered, it may be provided that the level of the liquid container is transferred to the data communication unit, that the liquid container is subsequently emptied, the level of the liquid container being continuously, in particular at predetermined time intervals, determined and transmitted to the data communication unit, that the difference between the level before the start of the emptying process and the last transmitted level is determined and the data communication unit
Fig. 1 shows a first representation of a liquid container from the side. Fig. 2 shows the liquid container shown in Fig. 1 from above. Fig. 3 shows the relationship between the capacitance between the two electrodes and the level of the liquid container at different electrode sizes. An embodiment of the invention will be described in more detail with reference to the following drawing figures. 4 shows a device according to the invention in the form of an insulin pen in a sectional view. 5 shows schematically the electrical connection of the individual components required for determining the capacitance.
4, an advantageous embodiment of the invention for determining the capacity is shown in more detail. The device shown in Fig. 4 comprises a cylindrical housing 11, in which a likewise cylindrical liquid container 1 (Fig. 1, 2) is introduced. The liquid container 1 can be removed from the housing 11 and replaced by a similar liquid container 1. On the outer jacket of the liquid container 1 electrodes 4, 5 are arranged, which extend along the liquid container 1. In this preferred embodiment, the two electrodes 4, 5 are circumferentially spaced from one another (FIG. 2) and extend over the entire length of the liquid container 1. The liquid container 1 further comprises an end wall 12, which is arranged on an end face of the cylindrical liquid container 1 , At the end wall 12 opposite end face of the cylindrical liquid container 1, a recess 13 is arranged. Inside the liquid container 1 is a liquid 14 to be administered to a person. This liquid 14 can escape through the recess 13 from the liquid container 1 and / or be applied. By moving the end wall 12 relative to the shell of the cylindrical liquid container 1, liquid 14 is forced out of the liquid container 1 and the volume of the liquid container 1 filled with liquid 14 is reduced.
Furthermore, the device shown in Fig. 4 has an administering means 3 or a dispensing unit with which liquid 14 can be administered from the liquid container 1 to a patient. As administration means 3, in particular, an injection needle is used. The delivery means 3 in this preferred embodiment of the invention comprises a feed 31 which presses an end wall 12 of the liquid container 1 normal to the axial direction of the cylindrical liquid container 1 into the liquid container 1 and thus liquid 14 at the end opposite this end wall 12 through a recess 13 through to an injection part 32 of the administering means 3. The injection part 32 and the liquid container 1 are in fluid communication with each other. The administering means 3 further comprises a drive 33 for the feed 31, which presses the feed 31 against the end wall 12 of the liquid container 1 and thus administers the liquid 14 located in the liquid container 1 to the respective patient.
The area between the end wall 12 and the end wall 12 opposite recess 13 is completely filled with liquid 14, the remaining area of the liquid container 1 is empty and filled in the present case with air. By emptying the liquid container 1, the liquid 14, which has a permittivity between 40 e0 and 80 e0, successively replaced by air, which has approximately a permittivity of e0. As a result of this reduction in the permittivity of the gap between the electrodes 4, 5, the capacitance between the electrodes 4, 5 on the jacket of the liquid container 1 is also reduced. The reduction in the capacity between the two electrodes 4, 5 caused by the emptying is shown in more detail in FIG.
The illustrated embodiment allows the determination of a level by means of capacitive measurement. However, the invention is not limited in principle to the level measurement shown here but can be used in general for the measurement of any capacity or each measured variable whose change is reflected in a change in capacitance. It is thus not necessary for the invention to be used to determine a filling level. Rather, the invention allows any determination of a capacity. In the following, the determination of the capacity is shown, which does not require an additional AC voltage source and without a battery or an accumulator.
In the present embodiment of the invention, the capacitance between the two electrodes 4, 5 is determined with the circuit shown in Fig. 5. The circuit comprises an antenna 8, which is connected to a communication unit 7. The antenna 8 is a coil antenna, such as used in NFC applications. The antenna 8 serves on the one hand the communication between the communication unit 7 with an external data communication device 40, such as a mobile phone, on the other hand, the antenna 8 also allows the transmission of energy required for measurement and communication from the data communication device 40 on the unit according to the invention for determining capacity.
The communication unit 7 may, in a particular embodiment, comprise a small buffer memory for buffering the amount of electrical energy required to operate the communication unit 7 during the measurement and communication with the data communication device 40. However, the buffer does not need to be dimensioned so large that its energy content for generating an AC signal to determine the capacitance between the two electrodes 4, 5 sufficient.
In principle, the measurement of the capacitance between the two electrodes as well as the capacitance of the reference capacitor 11 can be measured directly, the specific energy required for the measurement can be provided directly by the data communication device.
The preferred embodiment of the invention shown in this example has a second antenna 9 and a third antenna 10. The two terminals of the second antenna 9 are connected to the two electrodes 4, 5. In each case a voltage is applied between the two electrodes 4, 5, the amplitude of each of which depends on the capacitance of the respective capacitor. The terminals of the third antenna 10 are connected to a respective one of the electrodes of the reference capacitor 11.
In the present case, the second antennas 9 and the third antenna 10 have the same number of turns. However, this is not mandatory. Alternatively, a calibration offset could, for example, deliberately be generated by a different choice of number of turns, which facilitates the dimensioning of the reference capacitance, if necessary.
The electric field energy introduced by the external data communication device 40 and the frequency of the field generated by the external data communication device 40 are different depending on the type of the external data communication device 40. In order to avoid different measured values, which are caused by the nature of the external data communication device 40, the third antenna 10 is provided, which wraps around the same area as the second antenna 9. The two terminals of the third antenna 10 are connected to the two electrodes of a reference capacitor 11 connected. By comparing the voltage applied between the two electrodes 4, 5 with the voltage applied to the reference capacitor 11, a measured value for the capacitance independent of the respective external data communication device 40 can be obtained. The second and third antenna 9, 10 wrap around the same area. The diversified representation in FIGS. 4 and 5 serves merely to simplify and clarify the illustration. Since the second and third antennas 9, 10 encircle the same area, the relative position between the external data communication device 40 and the antennas 9, 10 also has no influence on the ratio between the voltage at the output of the reference capacitor 11 and the voltage between the two electrodes 4, 5th
An essential advantage of the invention is that no additional voltage generator and no additional accumulator are required for the determination of the capacitance between the two electrodes 4, 5 and optionally the capacitance of the reference capacitor 11, but the energy required to determine the respective capacitance directly from the can be removed from the data communication device 40 generated electromagnetic field.
The preferred embodiment of the invention shown in this example has two measuring circuits 6, 16, which are connected to the communication unit 7 and transmit all values measured by them to the communication unit 7. In the present case, the two measuring circuits 6, 16 each have a rectifier, a smoothing circuit connected downstream of the rectifier, and an ADC circuit connected downstream of the smoothing circuit. The result of the respective ADC circuit is supplied to the communication unit 7.
A capacitance and measured value determining unit 15 is provided, each of which determines the relationship between the voltage at the output of the reference capacitor 11 and the voltage between the two electrodes 4, 5 and makes this result available at its output and to which the communication unit 7 forwards , If necessary, a conversion of this ratio into a capacitance or a measured variable derived therefrom may be carried out, wherein the respective ratio is compared in each case with reference conditions ascertained by means of calibration determined beforehand for predetermined capacitance values. Thus, for example, the ascertained capacitance value Cm can be converted into the respective filling level quantity L of the liquid 14 in the liquid container 1 in accordance with the diagram shown in FIG. The communication unit 7 transmits this ratio or the respective converted measured variable to the external data communication device 40 on request.
In the present exemplary embodiment, the capacitance and measured value determining unit 15, the measuring circuits 6, 16 and the reference capacitor 11 are accommodated on a common chip 17. In an alternative development of the invention, the communication unit 7 can additionally be accommodated in the chip 17.
The administration means 3 is controlled in the present embodiment of the invention by a control unit, not shown, which is supplied to the voltage applied to the output of the comparison unit 15 measured value for the level of the liquid container 1. The control unit activates the administering means 3 until the level of the liquid container 1 is reduced by a predetermined amount. At most, the process can also be stopped when the feed has reached a stop. In this case, an error message can be issued, indicating that the respective liquid container 1 is empty and not the amount of liquid to be administered has been administered.
In order to determine which amount of liquid has been administered at once, in each case before and after the administration, the fill level L is determined, as described above. Thus, there is thus a first fill level L1 before administration and a second fill level L2 after the administration. If one forms the difference DL between the first and second fill levels, one obtains that amount of liquid which was administered in each case. During the administration of a liquid, the first level L1 can be stored before administration for the dosing of the respective liquid, and the second level can be determined continuously. When the difference DL between the first and second levels reaches a threshold, the administration is aborted. For this purpose, the respective delivery means 3 is deactivated, for example, the drive 33 is deactivated for the feed 31 and the feed 31 is stopped. No additional fluid 14 is administered or delivered.

权利要求:
Claims (16)
[1]
1. Device for determining the capacitance between two electrodes (4, 5) comprising - a measuring circuit (6) connected downstream of the electrodes (4, 5) for determining the capacitance between the two electrodes (4, 5), - one of the measuring circuit (6) downstream communication unit (7), and - a first antenna (8) with a coil-shaped structure and at least one winding connected to the communication unit (7), wherein the communication unit (7) transmits the measured values to an external data communication unit (7). 40), characterized by - a second antenna (9) having a coil-shaped construction and having at least one turn connected to the measuring circuit (6), the terminals of the second antenna (9) being directly or indirectly connected to the electrodes (4 , 5) are connected, so that upon excitation of the antenna (9) with an alternating electromagnetic field, an AC voltage to the electrodes (4, 5) wherein the measuring circuit (6) is designed for the direct or indirect measurement of the alternating voltage applied to the electrodes (4, 5) or of the alternating current flowing through the electrodes (4, 5), and - the output of the measuring circuit being directly or indirectly connected Communication unit (7) is supplied.
[2]
2. Device according to claim 1, characterized in that - one of the terminals of the second antenna (9) is connected to one of the two electrodes (4, 5), - the measuring circuit (6) for determining the amplitude of the voltage between the two electrodes (4, 5) is formed and holds at its output a measurement value corresponding to this amplitude available.
[3]
3. Device according to one of the preceding claims, characterized by: - a third antenna (10) with coil-shaped construction and with at least one winding, which wraps around the same area as the second antenna (9) and in particular has the same number of turns as the second Antenna (9), - a reference capacitor (11) having a predetermined capacity, wherein the terminals of the third antenna (10) are directly or indirectly connected to the electrodes of the reference capacitor (11), so that upon excitation of the third antenna (10) with a an alternating voltage applied to the electrodes of the reference capacitor (11), - a second measuring circuit (16) for the direct or indirect measurement of the reference capacitor (11) applied AC voltage or of the reference capacitor flowing through the alternating current and - one of the communication unit (7) upstream Capacity and / or measured value determination unit (15), d ie determines the ratio of the measured values determined by the measuring circuits (6, 16), in particular subjects them to a calibration function and / or converts them into a measured value derived from the capacitance and outputs them at their output, wherein the communication unit (7) transmits this ratio as a respective one Measured value for the amount of liquid in the liquid container (1) remaining liquid (14) is formed.
[4]
4. Apparatus according to claim 3, characterized in that in each case one of the terminals of the third antenna (10) is connected to one of the two electrodes (4, 5) of the reference capacitor (11), and that a second measuring circuit (16) designed to determine the amplitude of the voltage between the terminals of the reference capacitor (11) and the reference capacitor (11) is connected downstream, wherein the communication unit (7) has a further input which is connected to the output of the second measuring circuit (16)
[5]
5. Device according to one of claims 3 or 4, characterized in that the second antenna (9) and the third antenna (10), possibly also the antenna (8) wrap around the same area.
[6]
6. Device according to one of the preceding claims, characterized by a liquid container (1), on whose, in particular inner or outer surface, the two electrodes (4, 5) are arranged opposite each other and not touching, wherein preferably the capacitance between the two electrodes (4, 5) depends on the quantity of liquid (14) present in the liquid container (1) and wherein the measured value output by the measuring circuit (6) corresponds to the quantity of liquid (14) in the liquid container (1).
[7]
A device according to claim 6, characterized in that the liquid container (1) is in fluid communication with an administering means (3) which is preferably adapted for injection of this liquid (14) to a living being, * * • * * * • fc · · · · · · · · · · · ·
[8]
8. The device according to claim 7, characterized in that the administration means (3) is controlled by a control unit, which is supplied to the measured value for the level of the liquid container (1), wherein the control unit activates the delivery means until the level of the liquid container (1) is reduced by a predetermined amount.
[9]
9. Arrangement with a device according to one of the preceding claims and a data communication unit (40), wherein the data communication unit (40) for emitting electromagnetic waves to the first antenna (8), the second antenna (9) and optionally to the third antenna ( 10) is formed.
[10]
10. Arrangement according to claim 9, characterized in that the data communication unit (40) has a receiving unit for receiving the measured values delivered by the device as well as a memory for storing these measured values.
[11]
11. Arrangement according to claim 10, characterized in that the data communication unit (40) has a further control unit which receives at predetermined time intervals, the measured value for the level (L2) of the liquid container, the difference (DL) between the level (L2) and determines a stored in their memory level and sends a signal when this difference (DL) exceeds a predetermined threshold.
[12]
12. A method for determining the capacitance between two electrodes (4, 5) with a first antenna (8) for data communication and a second antenna (9) with coil-shaped structure and with at least one winding which directly or indirectly to the two electrodes (4 , 5) is connected so that upon excitation of the antenna (9) with an electromagnetic Wechseifeld an AC voltage to the electrodes (4, 5) is applied, characterized in that the second antenna (9) by a data communication device (40) with an electromagnetic Alternating field is excited and thus at the electrodes (4, 5) an alternating voltage is applied, and - that with the aid of the AC voltage, the capacitance between the two electrodes (4, 5) is determined, and the capacity or a value derived therefrom via the first antenna ( 8) is transmitted to the data communication device (40).
[13]
13. The method of claim 12 with a third antenna (10), which in particular wraps around the same area as the second antenna, and a reference capacitor (11) having a predetermined capacitance, wherein the terminals of the third antenna (10) directly or indirectly to the electrodes of the reference capacitor (11) are connected, so that upon excitation of the third antenna (10) with an alternating electromagnetic field an AC voltage to the electrodes of the reference capacitor (11) is applied, characterized in that - the third antenna (10) by the data communication device (40) is excited together with the second antenna (9) with an alternating electromagnetic field, whereby the reference capacitor (11) is applied an alternating voltage, and that with the aid of the AC voltage, the capacitance of the reference capacitor (11) is determined, and the ratio between the capacitance between the two Electrodes (4, 5) and the reference capacitor (11) to the D Data communication device (40) is transmitted.
[14]
14. The method according to claim 12 or 13 with liquid container (1), at the, in particular inner or outer surface, the two electrodes (4, 5) are arranged opposite each other and not touching, characterized in that the capacitance between the two electrodes ( 4, 5) or the ratio between the capacitance between the two electrodes (4, 5) and the reference capacitor (11) as a measure of the level (L) is considered and, in particular according to a calibration table, in a level (L) is converted ,
[15]
15. The method according to claim 14, characterized in that the filling level (L1) of the liquid container (1) is transmitted to the data communication unit (40) and that the transferred level (L1) in the data communication unit (40) or one related to her another data communication device is stored and is retrievable at a later date.
[16]
16. The method according to claim 15, characterized in that the level (L1) of the liquid container (1) to the data communication unit (40) is transferred, that the liquid container (1) is subsequently emptied, wherein continuously, in particular at predetermined time intervals, the level (L2) of the liquid container is determined and is transmitted to the data communication unit (40), that the difference (DL) between the level (L2) before the beginning of the emptying process and the last transmitted level (L2) is determined and the data communication unit (40) Signal transmits when this difference (DL) exceeds a predetermined threshold and the emptying of the Flüssigkeitsbehäiter (1) is interrupted after transmission of this signal.

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DE102016203912A1|2017-09-14|Detection device for detecting a value representing a dose of a dosing device and method for operating the same

DE3601730A1|1986-09-11|Method and device for identifying and controlling body fluid values

DE102016203903A1|2017-09-14|Detection device for detecting a value representing a dose of a dosing device and method for operating the detection device

同族专利:

公开号 | 公开日

IN2014DN07903A|2015-04-24|

RU2014142453A|2016-05-20|

WO2013138830A1|2013-09-26|

JP6140267B2|2017-05-31|

CN104395714B|2017-12-19|

CN104395714A|2015-03-04|

RU2617248C2|2017-04-24|

AT512504B1|2013-09-15|

CA2868098A1|2013-09-26|

EP2828627A1|2015-01-28|

JP2015512509A|2015-04-27|

US20150045727A1|2015-02-12|

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法律状态:
2019-11-15| MM01| Lapse because of not paying annual fees|Effective date: 20190322 |

优先权:

申请号 | 申请日 | 专利标题

ATA358/2012A|AT512504B1|2012-03-22|2012-03-22|Apparatus and method for determining the capacity|ATA358/2012A| AT512504B1|2012-03-22|2012-03-22|Apparatus and method for determining the capacity|

US14/386,960| US20150045727A1|2012-03-22|2013-03-08|Capacitive nfc-based fill level sensor for insulin pens|

CN201380026720.9A| CN104395714B|2012-03-22|2013-03-08|For novopen, liquid level sensor based on electric capacity NFC|

JP2015500709A| JP6140267B2|2012-03-22|2013-03-08|Capacitive filling degree sensor based on short-range wireless communication for insulin pen|

PCT/AT2013/050060| WO2013138830A1|2012-03-22|2013-03-08|Capacitive nfc-based fill-level sensor for insulin pens|

EP13713337.7A| EP2828627A1|2012-03-22|2013-03-08|Capacitive nfc-based fill-level sensor for insulin pens|

RU2014142453A| RU2617248C2|2012-03-22|2013-03-08|Filling level sensor of insulin pen, based on near-contact communication |

IN7903DEN2014| IN2014DN07903A|2012-03-22|2013-03-08|

CA2868098A| CA2868098A1|2012-03-22|2013-03-08|Capacitive nfc-based fill level sensor for insulin pens|

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