• 专利附录
  • 专利说明
  • 权利要求
  • 类似技术
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    • 专利摘要:
    A system is shown for measuring and recording the amount of liquid in an absorbent material, for example a filler in a diaper, which system comprises a sensor comprising an outer electrode and an inner electrode arranged in or around the absorbent material, and a transmitter arranged to apply an alternating voltage between the two electrodes, simultaneously measuring the capacitance between the two electrodes and calculating the status of the amount of liquid in the absorbent material. In one embodiment, the sensor further comprises a surface in electrical contact to the body of a person, and the transmitter is arranged to be able to calculate the status of the presence of a substance, for example, faeces, between the inner electrode and the body by either a capacitive or a resistive measurement between the inner electrode and the body.
    公开号:DK201300425A1
    申请号:DK201300425
    申请日:2013-07-12
    公开日:2015-01-26
    发明作者:Martin Ettrup
    申请人:Suma Care Aps;
    IPC主号:
    专利说明:

    System for measuring the amount of urine and faeces in a diaper
    The present invention relates to a system for measuring the amount of urine and faeces in a diaper, where one or more resistive and / or capacitive sensors are used to determine the degree of filling in the diaper.
    BACKGROUND
    Alarms in connection with measuring the presence of urine in diapers, underwear and sheets etc. is known technology in the form of various enuresis and incontinence products.
    The traditional products are characterized in that they give an alarm signal as soon as a liquid is present on the sensor, a so-called immediate alarm. The products typically work by performing a resistive measurement over a sensor where, in a normal situation (when the diaper is dry), no current flows between the electrodes. In an alarm situation, an electrical connection is created between the electrodes via the liquid that occurs between the electrodes, after which a given current will flow from one electrode to the other. The fluid, in these cases urine, acts as a simple contact between two or more electrodes.
    Examples of these systems are disclosed in US 7,700,821 B2 and US 7,667,608 B2, and the purpose of such systems is precisely to raise an alarm as soon as possible, as urine on the sensor is an undesirable situation for children who are wetter, or in connection with incontinence patients. The traditional resistive instant alarms are available in a myriad of variants and, as mentioned earlier, are included in diapers, panties, underwear, sheets, bedding and beds, etc., and are all characteristic of the above technology and function.
    Criteria for when the need for changing diapers for children and people with incontinence is met is usually determined by subjective assessments of the closest relatives or carers based on the elapsed time since the last shift or by noting the level of diaper filling. There are several disadvantages to these methods. First, they provide a large variation in the utilization rate of the diapers, and thus a quantity of diapers will be changed which will still have an unused absorbent capacity. Secondly, the diaper's capacity may be exceeded, resulting in situations where the diaper user has an unusually large urine output. Finally, this practice of subjective shift assessments also requires time and attention for relatives and carers, regardless of the assessment method used.
    Presence of faeces in the diaper is an undesirable condition as it can cause skin damage to the wearer. It is only detected by visual inspection or if the user can tell. This is not appropriate.
    This practice also raises concerns about whether the many bladder inflammation in diaper users is due to the environment being too humid for too long. The mentioned practices make it difficult to collect and compare data that could help improve or even prevent various side effects by using diapers.
    BRIEF DESCRIPTION OF THE INVENTION
    It is an object of the present invention to provide a more advanced alarm system which does not generate an either / or alarm, but uses a more differentiated measurement method with the option of self-selected alarm levels which can be customized to the institution or user. In this way, the system can not only support the possibilities to improve conditions for the diaper user, but also the working environment and the possibilities of preventing inconveniences.
    Such a system is provided with the present invention which relates to a system for measuring and recording the amount of liquid in an absorbent material, for example a filler in a diaper, which system comprises a sensor comprising an outer electrode and an inner electrode which is arranged in or around the absorbent material and a transmitter arranged to apply an alternating voltage between the two electrodes simultaneously measures the capacitance between the two electrodes and calculates the amount of liquid in the absorbent material based on the measured capacitance .
    To ensure that the system is intact and the capacitance measurement is correct, it will be advantageous to check the so-called "dissipation factor", which is an expression of an unwanted resistive coupling between the two electrodes. This can be done, for example, by measuring the ohmic resistance between the two electrodes.
    Such a system is advantageous because it is continuously capable of measuring and transmitting information about the amount of liquid in a given absorbent blank, such as a diaper.
    Likewise, the invention can measure and transmit an alarm when faeces occur in the diaper, thus greater insight can be gained when the need for diaper change is present. In one embodiment of the invention, the sensor further comprises a surface arranged to be in electrical contact with the body of a person, and the transmitter is arranged to be able to apply an alternating voltage between the inner electrode and this surface, simultaneously measuring the capacitance between the sensor's interior electrode and this body and calculate the status of the presence of a substance, for example, faeces, between the inner electrode and the body based on the measured capacitance.
    As described above, controlling the so-called "dissipation factor" which is an expression of an undesirable resistive coupling between the inner electrode and the body will be advantageous at the same time as the capacitance measurement. This can be done, for example, by measuring the ohmic resistance between the inner electrode and the body. In another embodiment of the invention, the sensor further comprises a surface arranged to be in electrical contact with the body of a person, and the transmitter is arranged to be able to measure an ohmic resistance between the inner electrode and this surface and calculate the status of the presence. of a substance, for example, faeces, between the inner electrode and the body based on the measured resistance. Thus, in these embodiments, the invention can measure and transmit an alarm when faeces occur in the diaper so that greater insight can be obtained when the need for diaper change is present. In one embodiment of the invention, a temperature meter is arranged in connection with the surface arranged to be in electrical contact with the body of a person.
    Such a temperature gauge could, among other things, be used to check that the surface is in fact in contact with the body as desired. Also, in some cases it can be used to measure the person's body temperature. In one embodiment of the invention, the transmitter is further arranged to be able to transmit signals representative of the calculated statuses wirelessly to one or more monitoring stations.
    Thus, the invention allows for remote monitoring of fluid quantity status and presence of e.g. faeces. More specifically, in this embodiment, the invention can be arranged to signal when an optimal, uniform and objective criterion, for example for diaper change, is met. In one embodiment of the invention, the transmitter is equipped with a gyroscope and / or an accelerometer.
    Using a gyroscope and / or an accelerometer, it is possible to determine the spatial orientation of the system (and, for example, a person using the system), which allows the measurement algorithm to be adjusted accordingly and to make better use of the filling capacity of the filler. In one embodiment of the invention, the amplitude of the alternating voltage is between 0.5 V and 15 V, preferably between 2 V and 10 V, most preferably between 3 V and 6 V. In one embodiment of the invention, the frequency of the alternating voltage is between 1 kHz and 50 kHz, preferably between 5 kHz and 25 kHz, most preferably between 8 kHz and 12 kHz.
    Amplitudes and frequencies within these ranges have been found to give good measurement results while at the same time implying that persons using the invention do not register or be affected by the applied AC voltage. In one embodiment of the invention, the AC voltage is applied at predetermined time intervals of between 5 minutes and 30 minutes. Applying the AC voltage at such time intervals has been found to give good measurement results. In one embodiment of the invention, the signal representative of the amount of liquid in the filler represents an absolute amount of liquid, e.g. 300 ml. In one embodiment of the invention, the signal representative of the amount of liquid in the filler represents a relative amount of liquid, e.g. 20% of the total capacity of the absorbent material.
    Depending on the application of the invention, it may be most advantageous to define the system so that either absolute or relative values are calculated and possibly form the basis for determining whether a predetermined criterion is met. In one embodiment of the invention, the sensor is located externally on a diaper with the outer electrode and the inner electrode located outside the diaper's outward and inward surfaces. In one embodiment of the invention, the sensor is located internally in a diaper with the outer electrode and the inner electrode between the outward and inward facing surfaces of the diaper. In one aspect of the invention, it relates to a method for measuring and recording the amount of liquid in an absorbent material, for example a filler in a diaper, comprising the steps of: applying an alternating voltage between two electrodes arranged in or about the absorbent material, simultaneously measuring the capacitance between the two electrodes, and calculating the status of the amount of liquid in the absorbent material based on the measured capacitance. In one embodiment of the invention, the method further comprises the following steps: applying an alternating voltage between an electrode and a surface in electrical contact with the body of a person, simultaneously measuring the capacitance between the electrode and that surface, and calculating the status of the presence of an electrode. substance, for example, faeces, between the inner electrode and the body based on the measured capacitance.
    FIGURES
    A few embodiments of the present invention are described in more detail below with reference to the attached figures, in which
    FIG. 1A shows the layer structure seen from the inside of an external use sensor according to an embodiment of the invention,
    FIG. 1B shows the layer structure seen from the inside of a modified variant of the sensor shown in FIG. 1A,
    FIG. 2 shows a section of cross section A-A in FIG. 1A,
    FIG. 3 shows another section of cross section A-A of FIG. 1A,
    FIG. 4 shows cross section B-B of FIG. 1A,
    FIG. 5 is a front view of an associated transmitter;
    FIG. 6 shows the same transmitter as in FIG. 5 seen from the back,
    FIG. 7 shows the same transmitter as in FIG. 5 seen from the left side,
    FIG. 8 shows the same transmitter as in FIG. 5 seen from the underside,
    FIG. 9 is a perspective view of an assembled unit according to an embodiment of the invention with a diaper, sensor as in FIG. 1A and transmitter as in FIG. 5,
    FIG. 10 shows the layer structure from the inside of a diaper with a first type (Type I) internal sensor according to an embodiment of the invention,
    FIG. 11 shows a section of cross section C-C of FIG. 10,
    FIG. 12A shows another portion of cross section C-C of FIG. 10,
    FIG. 12B shows a cross section similar to FIG. 12A of a modified variant of the diaper with sensor shown in FIG. 10,
    FIG. 13 shows cross sections D-D of FIG. 10,
    FIG. 14 shows the same diaper as in FIG. 10 with a built-in sensor seen from the inside,
    FIG. 15 is a front view of an associated transmitter;
    FIG. 16 shows the same transmitter as in FIG. 15 from the back,
    FIG. 17 shows the same transmitter as in FIG. 15 seen from the left side,
    FIG. 18 shows the same transmitter as in FIG. 15 seen from the underside,
    FIG. 19 is a perspective view of an assembled unit according to an embodiment of the invention with diaper, sensor as in FIG. 10 and transmitter as in FIG. 15,
    FIG. Fig. 20 shows the layer structure from the inside of a diaper with a second type (Type II) sensor according to an embodiment of the invention;
    FIG. 21 shows a portion of cross-section E-E of FIG. 20,
    FIG. 22 is a front view of an associated transmitter,
    FIG. 23 shows the same transmitter as in FIG. 22 from the back,
    FIG. 24 shows the same transmitter as in FIG. 22 from the left side,
    FIG. 25 shows the same transmitter as in FIG. 22 from the bottom,
    FIG. 26 is a perspective view of an assembled unit according to an embodiment of the invention with a diaper, sensor as in FIG. 20 and transmitter as in FIG. 22
    FIG. 27 shows the interior structure of the diaper with a third type (Type III) internal sensor according to an embodiment of the invention,
    FIG. 28 shows a portion of cross section F-F of FIG. 27,
    FIG. 29 shows another portion of cross section F-F of FIG. 27,
    FIG. 30 shows cross section G-G of FIG. 27,
    FIG. 31 is a front view of an associated transmitter,
    FIG. 32 shows the same transmitter as in FIG. 31 from the back,
    FIG. 33 shows the same transmitter as in FIG. 31 from the left side,
    FIG. 34 shows the same transmitter as in FIG. 31 from the bottom,
    FIG. 35 is a perspective view of an assembled unit according to an embodiment of the invention with diaper, sensor as in FIG. 27 and transmit as in FIG. 31st
    The figures are given as examples of how the present invention can be practiced and should not be construed as limiting the scope of protection as determined by the appended claims. DETAILED DESCRIPTION OF THE INVENTION Exterior sensor
    FIG. 1A shows an external sensor 1, with a skin-friendly, moisture-blocking electrically insulating carrier 2, to which an outer electrode 3 is mounted. The outer electrode 3 is made of an electrically conductive material, e.g. copper, aluminum, iron, graphite printing or a conductive polymer, and may be mounted as a tape with adhesive or applied in a printing process directly to the carrier medium 2. The dielectric 4 shown is an insulator and may be of foam tape, tape, paper or a elastic liquid polymer which is applied in a printing process and subsequently solidifies. The inner electrode 5 is made of an electrically conductive material, e.g. copper, aluminum, iron, graphite printing or a conductive polymer, and may be mounted as a tape with adhesive or applied in a printing process directly to the dielectric 4 and the carrier medium 2. A pushbutton 8 creates an electrical connection from the inner electrode 5 of the sensor 1 to a contact point on the outside of the sensor 1 through the dielectric 4 and the carrier medium 2. Finally, the sensor 1 shown comprises a moisture-blocking electrically insulating filler 6, which may be a foam tape or an elastic liquid polymer which is applied in a printing process and subsequently solidifies, and a double-sided adhesive 7, the purpose of which is to ensure a solid and tight fitting to the diaper.
    FIG. 1B shows a modified variant of the sensor of FIG. 1A, where a portion of the moisture-blocking electrically insulating material 2 is removed so that part of the inner electrode 5 and part of the adhesive layer 7 are exposed. Thus, in this variant, an electric current may run between the exposed portion of the inner electrode 5 and a contact (not shown in this figure) in electrical contact with the body of the diaper wearer. A measurement of the ohmic resistance between the inner electrode 5 and this body contact can be used to determine whether there is a stool between the inner electrode 5 and the body.
    FIG. 2 shows the upper part of cross section A-A of the external sensor 1 of FIG. 1A, where layers 2-7 appear as described above. Another pushbutton 9 creates an electrical connection from the outer electrode 3 of the sensor 1 to a contact point on the outside of the sensor 1 through the carrier medium 2.
    FIG. 3 shows the lower part of cross section A-A of the external sensor 1, where layers 2-7 appear, as described above. The length of the outer electrode 3 and the dielectric 4 are adapted to the length of the diaper and stop at the posterior edge of the diaper, the inner electrode 5 proceeding at a distance corresponding to the distance from the trailing edge of the diaper to a point inside the diaper where faeces are expected to be placed.
    FIG. 4 shows cross section B-B of the external sensor 1, where layers 2-7 appear, as described above.
    FIG. 5 shows a front view of a transmitter 10, where a housing 11 contains electronics (measuring circuits, power supply and radio module etc.) and a battery, where a rubber hinge 12 is mounted for fastening the housing 11 over the front of the diaper by means of, for example, a magnetic contact, and a body contact 13 creates an electrical connection to the user's body. The transmitter 10, together with the diaper and sensor 1, constitutes a fully functioning unit 16 in the overall system.
    FIG. 6 is a rear view of the same transmitter 10, where a button 14 acts as a counterpart to the push button 8 for the inner electrode 5 and another button 15 acts as a counterpart to the push button 9 for the outer electrode 3. The distance of the buttons 14, 15 corresponds to the distance between pushbutton 8 and pushbutton 9 on the sensor 1 (see Fig. 2), so that the transmitter 10 can be easily mounted on the sensor 1.
    FIG. 7 shows the transmitter 10 seen from the left side with the housing 11, the rubber hinge 12 and the body contact 13.
    FIG. 8 shows the transmitter 10 seen from below with the housing 11 and the second button 15.
    FIG. 9 is a perspective view of a diaper mounted on the external sensor 1 and the transmitter 10, with the sensor 1 being centered longitudinally of the diaper. These three components together constitute a self-functioning unit 16 of the total system.
    The unit 16 operates by transmitter 10 applying an alternating voltage of, for example, 5 Vac at a frequency of, for example, 10 kHz between the two electrodes 3, 5 and the user's body via the body contact 13 for a predetermined time interval of, for example, 5 minutes. At the same time, the transmitter 10 measures the capacitance between the outer electrode 3 and the inner electrode 5 and the capacitance between the inner electrode 5 and the user's body via the body contact 13. The measured capacitance between the outer electrode 3 and the inner electrode 5 is equivalent to an expression of the diaphragm filling rate. fluid, while the capacitance between the inner electrode 5 and the user's body is equivalent to an expression of the presence of faeces in the diaper or not.
    The correlation between the capacitance and the amount of fluid in the diaper is approximately linear with an always positive slope coefficient (the higher the measured capacitance, the more the presence of liquid). The width of the inner electrode 5 is a maximum of 75% of the width of the outer electrode 3 (see Fig. 4). This creates an electric field, which is influenced by the dielectric property of the diaper filler, where the dielectric constant for water (and urine) is approx. 80 times greater than the dielectric constant for air. It is this difference that is exploited in this construction.
    Built-in sensor (Type I)
    FIG. 10 shows the layer structure of diaper 17 with an internal sensor (Type I) seen from the inside, where an outer electrode 19 is applied to the inside 18 of the outer layer of the diaper 17. The outer electrode 19 is made of an electrically conductive material, e.g. copper, aluminum, iron, graphite printing or a conductive polymer, and may be mounted as a tape with adhesive or applied in a printing process directly to the inside of diaper 17. A tightly sealing, moisture-blocking and electrically insulating layer 20 is mounted / printed over electrode 19 and on the sides thereof to ensure that the electrode 19 has an electrically insulating surface. This insulating layer 20 may be a polyester tape, a printed wax or other material having the characteristics described. At the top of the outer electrode 19 over the active (absorbent) region of the diaper 17, there is a round opening in the insulating layer 20. This opening acts as the contact area of the outer electrode 19.
    A liquid-absorbing layer of, for example, paper, wax, cotton, polymer or calcium carbonate forms a dielectric 21, the purpose of which is to pass urine from the fluid-absorbing layer 24 of the diaper 17 between the outer electrode 19 and an inner electrode 22. The dielectric 21 adheres to it. insulating layer 20 and to another moisture-blocking and electrically insulating layer 23. The inner electrode 22 is made of an electrically conductive material, e.g. copper, aluminum, iron, graphite printing or a conductive polymer, and may be mounted as a tape with adhesive or applied in a printing process directly to this second insulating layer 23. This layer 23 completely encloses the inner electrode 22 and consists of an electrical insulator which is mounted or pressed and provides a tightly sealing, moisture-blocking and electrically insulating layer over the electrode 22 and on the sides thereof. The layer 23 may be a polyester tape, a printed wax or other material having the properties described. At the top of the inner electrode 22 above the active (absorbent) region of the diaper 17, there is a round opening in the insulating layer 23. This opening acts as the contact area of the inner electrode 22.
    At the rear of the diaper 17, the inner electrode 22 is passed over the fluid-absorbing layer 24 of the diaper 17 into the diaper 17 to the area where faeces are expected to be placed. The outside of the inner layer 26 of the diaper 17 is constituted by a standardized and skin-friendly surface. The electrodes 19, 22 and the dielectric 21 are centrally located in the longitudinal direction of the diaper 17.
    FIG. 11 shows the upper part of cross section CC of the front part of the diaper 17, where the layers 18-20, 22, 23 and 26 appear, as described above, with the two openings into the outer electrode 19 and the inner electrode 22, respectively, which are to be act as electrical contacts for a transmitter 28 (not shown in Fig. 11).
    FIG. 12A shows the lower portion of cross-section C-C of the rear portion of the diaper 17, with layers 18-27 appearing as described above. The length of the outer electrode 19 and the dielectric 21 is adapted to the length of the diaper 17 and stops at the trailing edge of the diaper 17, while the inner electrode 22 is extended and proceeds at a length 27 to the point internally of the diaper 17 where faeces are expected to be placed.
    FIG. 12B shows a cross section similar to FIG. 12A of a modified variant of diaper 17 with sensor, wherein a portion of the moisture-blocking electrically insulating material 25 is removed so that a portion of the lead 27 of the inner electrode 5 is no longer electrically insulated. Thus, in this variant, an electric current may run between the exposed portion of the extension 27 of the inner electrode 5 and a body contact 31 (not shown in this figure) in electrical contact with the body of the wearer of the diaper. A measurement of the ohmic resistance between the extension 27 of the inner electrode 5 and this body contact can be used to determine whether there is a stool between the extension 27 of the inner electrode 5 and the body.
    FIG. 13 shows cross sections D-D of diaper 17, with layers 18-27 appearing as described above.
    FIG. 14 shows the total diaper 17 with built-in sensor seen from the inside.
    FIG. 15 is a front view of the transmitter 28, where a housing 29 contains electronics (measuring circuits, power supply and radio module, etc.) and a battery in which a rubber hinge 30 is mounted for securing the housing 29 over the leading edge of the diaper 17, for example by means of a magnetic contact, and wherein a body contact 31 creates an electrical connection to the user's body. The transmitter 28, together with the diaper 17 with the built-in sensor, forms a complete functioning unit 34 in the overall system.
    FIG. 16 shows the same rear view transmitter 28 with an electrical contact 33 for connection to the inner electrode 22 and a second electrical contact 32 for connection to the outer electrode 19. The center distance between the two contacts 32, 33 corresponds to the center distance between the outer electrode 19 and the inner electrode 22 (see Fig. 14) so that the transmitter 28 can be easily mounted on the built-in sensor of the diaper 17.
    FIG. 17 shows the transmitter 28 seen from the left side with the housing 29, the rubber hinge 30, the body contact 31 and the electrode contacts 32, 33.
    FIG. 18 shows the transmitter 28 seen from below with the housing 28 and one of the electrode contacts 33.
    FIG. 19 shows the diaper 17 with built-in sensor (Type I) and the transmitter 28 seen in perspective.
    These two components together constitute a self-functioning unit 34 of the total system.
    The unit 34 functions by transmitter 28 applying an alternating voltage of, for example, 5 Vac at a frequency of, for example, 10 kHz between the two electrodes 19, 22 and the user's body via the body contact 31 for a predetermined time interval of, for example, 5 minutes. Transmitter 28 simultaneously measures the capacitance between the outer electrode 19 and the inner electrode 22 and the capacitance between the inner electrode 22 and the user's body via the body contact 31. The measured capacitance between the outer electrode 19 and the inner electrode 22 is equivalent to an expression of the diaphragm 17's degree of filling. of liquid, while the capacitance between the inner electrode 22 and the user's body is equivalent to an expression of the presence of faeces in the diaper 17 or not.
    The relationship between the capacitance and the amount of liquid in the diaper 17 is approximately linear with an always positive slope coefficient (the higher the measured capacitance, the more presence of liquid). The construction works by the dielectric 21 absorbing liquid at the same rate as the filler 24 being wetted. As the dielectric 21 changes character from air to urine, the dielectric constant changes by a factor of approx. 80, and it is this difference that is exploited in this construction.
    Built-in sensor (Type II)
    FIG. 20 shows the layer structure of a diaper 35 with an internal sensor (Type II) seen from the inside, where an outer electrode 36 (see Fig. 21) is applied to the inside 18 of the outer layer of the diaper 35. The outer electrode 36 is made of an electrically conductive material, e.g. copper, aluminum, iron, graphite printing or a conductive polymer, and may be mounted as a tape with adhesive or applied in a printing process directly to the inside of diaper 35. A tightly sealing, moisture-blocking and electrically insulating layer 37 is mounted / printed over electrode 36 and on the sides thereof to ensure that the electrode 36 has an electrically insulating surface. This insulating layer 37 may be a polyester tape, a printed wax or other material having the characteristics described. At the top of the electrode 36 over the active (absorbent) region of the diaper 35, a push button 38 is mounted which creates an electrical connection from the outer electrode 36 of the sensor to a contact point on the outside of the diaper 35. This pushbutton 38 acts as an electrical conductor for the outer electrode 36.
    A liquid-absorbing layer of, for example, paper, wax, cotton, polymer or calcium carbonate forms a dielectric 21, the purpose of which is to pass urine from the liquid-absorbing layer 24 of the diaper 35 between the outer electrode 36 and an inner electrode 39. The dielectric 21 adheres to it. insulating layer 37 and to another moisture-blocking and electrically insulating layer 40. The inner electrode 39 is made of an electrically conductive material, e.g. copper, aluminum, iron, graphite printing or a conductive polymer, and may be mounted as a tape with adhesive or applied in a printing process directly to this second insulating layer 40. This layer 40 completely encloses the inner electrode 39 and consists of an electrical insulator which is mounted or pressed and provides a tightly sealing, moisture-blocking and electrically insulating layer over the electrode 39 and on the sides thereof. The layer 40 may be a polyester tape, a printed wax or other material having the characteristics described. At the top of the inner electrode 39 over the active (absorbent) region of the diaper 35, a push button 41 is mounted which creates an electrical connection from the sensor's inner electrode 39 to a contact point on the outside of the diaper 35. This pushbutton 41 acts as an electrical conductor for the inner electrode 39.
    At the rear of the diaper, the inner electrode 39 is passed over the fluid-absorbing layer 24 of the diaper 35 into the diaper 35 to the area where the faeces are expected to be placed. The outside of the inner layer 26 of the diaper 17 is constituted by a standardized and skin-friendly surface. The electrodes 36, 39 and the dielectric 21 are centrally located in the longitudinal direction of the diaper 35 and are constructed in the same manner as shown in FIG. 12A and FIG. 13th
    FIG. 21 shows a portion of cross-section EE of the front portion of the diaper 35, where layers 18, 26, 36, 37, 39 and 40 appear, as described above, with the two push buttons 41 and 38 in to the outer electrode 36 and the inner electrode, respectively. 39, which pushbuttons 38, 41 act as electrical contacts to a transmitter 43 (not shown in Fig. 21). Also seen is a body contact 42, the purpose of which is to create an electrical connection between the transmitter 43 and the user's body.
    FIG. 22 is a front view of this transmitter 43, where a housing 44 contains electronics (measuring circuit, power supply and radio module, etc.) and a battery. The transmitter 44 together with the diaper 35 with built-in sensor forms a complete functioning unit 48 in the overall system.
    FIG. 23 is a rear view of the transmitter 43, where a button 46 acts as a counterpart to the push button 41 for the inner electrode 39, and another button 47 acts as a counterpart to the push button 38 for the outer electrode 36. The center distance between the buttons 46, 47 corresponds to the center distance between the two push buttons 38 and 41 (see Fig. 21) so that the transmitter 43 and diaper 35 can be easily assembled. A further button 45 acts as a counterpart to the body contact 42 and creates an electrical connection to the user's body through the diaper 35. This button 45 is located at the same distance from the other two buttons 46, 47 as the body contact 42 is located to the push buttons 41 and 38, thus that transmitter 43 and diaper 35 can be easily assembled.
    FIG. 24 shows the transmitter 43 seen from the left side with the housing 44.
    FIG. 25 shows the transmitter 43 seen from below with the housing 44 and the buttons 45-47.
    FIG. 26 shows the diaper 35 with built-in sensor (Type II) and the transmitter 43 seen in perspective. These two components together constitute a self-functioning unit 48 of the total system.
    The unit 34 functions by transmitter 43 applying an alternating voltage of, for example, 5 Vac at a frequency of, for example, 10 kHz between the two electrodes 36, 39 and the user's body via the body contact 42 for a predetermined time interval of, for example, 5 minutes. The transmitter 43 simultaneously measures the capacitance between the outer electrode 36 and the inner electrode 39 and the capacitance between the inner electrode 39 and the user's body via the body contact 42. of liquid, while the capacitance between the inner electrode 39 and the user's body is equivalent to an expression of the presence of faeces in the diaper 35 or not.
    The correlation between the capacitance and the amount of liquid in the diaper 35 is approximately linear with an always positive slope coefficient (the higher the measured capacitance, the more presence of liquid). The construction works by the dielectric 21 absorbing liquid at the same rate as the filler 24 being wetted. As the dielectric 21 changes character from air to urine, the dielectric constant changes by a factor of approx. 80, and it is this difference that is exploited in this construction. In the same manner as described for the Type I sensor above, the Type II sensor can be modified by removing a portion of the moisture-blocking electrically insulating layer 40 around the inner electrode 39 such that a measurement of the ohmic resistance between the inner electrode 39 and the body contact 42 can be used to determine whether there is a stool between the inner electrode 39 and the body.
    Built-in sensor (Type III)
    FIG. 27 shows the layer structure of a diaper 49 with an internal sensor (Type II) seen from the inside, where an outer electrode 50 (see Fig. 28) is applied to the inside 18 of the outer layer of the diaper 49. The outer electrode 50 is made of an electrically conductive material, e.g. copper, aluminum, iron, graphite printing or a conductive polymer, and may be mounted as a tape with adhesive or applied in a printing process directly to the inside of diaper 35. A tightly sealing, moisture-blocking and electrically insulating layer 51 is mounted / printed over electrode 50 and on the sides thereof to ensure that the electrode 50 has an electrically insulating surface. This insulating layer 51 may be a polyester tape, a printed wax or other material having the properties described.
    A moisture barrier electrical insulator of e.g. foam tape, tape, paper or an elastic liquid polymer which is applied in a printing process and subsequently solidifies to form a dielectric 52. This dielectric 52 adheres to the insulating layer 51 and to another moisture-blocking and electrically insulating layer 54. electrode 53 is made of an electrically conductive material, e.g. copper, aluminum, iron, graphite printing or a conductive polymer, and may be mounted as a tape with adhesive or applied in a printing process directly to this second insulating layer 54. This layer 54 completely encloses the inner electrode 53 and consists of an electrical insulator which is mounted or pressed and provides a tightly sealing, moisture-blocking and electrically insulating layer over the electrode 53 and on its sides. The layer 54 may be a polyester tape, a printed wax or other material having the properties described.
    At the rear of the diaper 49, the inner electrode 53 is passed over the fluid-absorbing layer 24 of the diaper 49 into the diaper 49 to the area where the faeces are expected to be placed. The outside of the inner layer 26 of the diaper 17 is constituted by a standardized and skin-friendly surface. The electrodes 50, 53 and the dielectric 52 are centrally located in the longitudinal direction of the diaper 35, as shown in FIG. 27th
    FIG. 28 shows a portion of cross-section FF of the front portion of diaper 49 where layers 18, 26, 50, 51, 53 and 54 appear, as described above, with the two push buttons 56, 57 in to outer electrode 50 and inner electrode, respectively. 53, which push buttons 56, 57 act as electrical contacts for a transmitter 58 (not shown in Fig. 28). Also seen is a body contact 42, the purpose of which is to create an electrical connection between the transmitter 56 and the user's body.
    FIG. 29 shows the lower section of cross section F-F of the rear portion of diaper 49, where layers 18, 24, 26 and 50-55 appear, as described above. The length of the outer electrode 50 and the dielectric 52 are aligned with the length of the diaper 49 and stop at the trailing edge of the diaper 49, and while the inner electrode 53 is extended and continues at a length 53 to the interior of the diaper 49 where the faeces are expected to be located. .
    FIG. 30 shows cross sections G-G of diaper 49, with layers 18, 24, 26 and 50-55 appearing as described above.
    FIG. 31 is a front view of the transmitter 58, where a housing 59 contains electronics (measuring circuit, power supply and radio module, etc.) and a battery. The transmitter 58, together with the diaper 49 with the built-in sensor, forms a complete functioning unit 63 in the overall system.
    FIG. 32 is a rear view of the transmitter 58 where a button 60 acts as a counterpart to the body contact 42 and thus creates an electrical connection to the user's body through the diaper 49. A second button 61 acts as a counterpart to the push button 57 for the inner electrode 53, and a third button 62 acts as a counterpart to the push button 56 for the outer electrode 50. The center distance between the buttons 60-62 corresponds to the center distance between the three push buttons 42, 56 and 57 (see Fig. 28), so that the transmitter 58 and the diaper 49 can be easily assembled.
    FIG. 33 shows the transmitter 58 seen from the left side with the housing 59.
    FIG. 34 shows the transmitter 58 seen from below with the housing 59 and the third button 62.
    FIG. 26 shows the diaper 49 with built-in sensor (Type III) and the transmitter 58 seen in perspective. These two components together constitute a self-functioning unit 63 of the total system.
    The unit 63 operates by transmitter 58 applying an AC voltage of, for example, 5 Vac at a frequency of, for example, 10 kHz between the two electrodes 50, 53 and the user's body via the body contact 42 for a predetermined time interval of, for example, 5 minutes. The transmitter 58 simultaneously measures the capacitance between the outer electrode 50 and the inner electrode 53 and the capacitance between the inner electrode 53 and the user's body via the body contact 42. The measured capacitance between the outer electrode 50 and the inner electrode 53 is equivalent to an expression of the diaphragm 49's degree of filling. of liquid, while the capacitance between the inner electrode 53 and the user's body is equivalent to an expression of the presence of faeces in the diaper 49 or not.
    The correlation between the capacitance and the amount of liquid in the diaper 49 is approximately linear with an always positive slope coefficient (the higher the measured capacitance, the more presence of liquid). The width of the inner electrode 53 is a maximum of 75% of the width of the outer electrode 50 (see Fig. 30). This creates an electric field which is influenced by the dielectric property of diaper filler 24 (see Fig. 30), where the dielectric constant for water (and urine) is approx. 80 times greater than the dielectric constant for air. It is this difference that is exploited in this construction. In the same manner as described for the Type I sensor above, the Type II sensor can be modified by removing a portion of the moisture-blocking electrically insulating layer 55 around the inner electrode 53, such that a measurement of the ohmic resistance between the inner electrode 53 and the body contact 42 can be used to determine whether there is a stool between the inner electrode 53 and the body.
    REFERENCE LIST 1. Complete retrofitted exterior sensor 2. Moisture-proof electrical insulating carrier for sensor 3. External electrode of capacitive sensor 4. Non-moisture absorbing insulator layer (dielectric) 5. Inner electrode of capacitive sensor 6. Moisture-blocking electric insulating filler for sensor 7. Adhesive layer 8 Pushbutton for electrical connection to inner electrode 9. Pushbutton for electrical connection to outer electrode 10. Transmitter (measuring and transmitting unit) 11. Housing containing PCB and battery etc. 12. Rubber hinge for attachment and contact 13. Body contact 14. Counterpart for push-button for internal electrode 15. Counterpart for push-button for outer electrode 16. Overall functioning unit with diaper, sensor and transmitter in perspective 17. Layer split stay with built-in sensor (type I ) 18. Inside of diaper outer layer 19. Outer capacitive sensor electrode 20. Moisture-resistant electrically insulating layer 21. Liquid-absorbing layer (dielectric) 22. Inner electrode of capacitive sensor 23. Moisture-blocking electrical insulating layer 24. Moisture-absorbing filler in diaper 25. Moisture barrier electrically insulating layer 26. Exterior of diaper inner layer 27. Inner electrode pass 28. Transmitter (measuring and transmitting unit) 29. Housing containing printed circuit board and battery etc. 30. Rubber hinge for attachment and contacts 31. Body contact 32. Contact for external electrode 33. Contact for internal electrode 34. Overall functioning unit with diaper and transmitter seen in perspective 35. Layered diaper with built-in sensor (type II) 36. Outer electrode of capacitive sensor 37. Moisturizing electrical insulating layer 38. Push button for connection to outer electrode 39. Inner electrode of capacitive sensor 40. Moisturizing electrical insulating layer 41. Push button for connection to internal electrode 42. Body contact 43. Transmitter (measuring and transmitting unit) 44 .House containing PCB and battery etc. 45. Push-button for connection to body contact 46. Push-button for connection to internal electrode 47. Push-button for connection to external electrode 48. Total operating unit with diaper and transmitter in perspective 49. Layered diaper with built-in sensor (type III) 50. Outer electrode of capacitive sensor 51. Moisturizing electrical insulating layer 52. Non-moisture absorbing electrical insulating layer (dielectric) 53. Inner electrode of capacitive sensor 54. Moisturizing electrically insulating layer 55. Moisturizing electrical insulating layer 56. Push button for connection to outer electrode 57. Push button for connection to internal electrode 58. Transmitter (measuring and transmitting unit) 59. Housing containing PCB and battery etc. 60. Counterpart for body contact 61. Contact for internal electrode 62. Contact for external electrode 63. Total functioning unit with diaper and transmitter seen in perspective
    权利要求:
    Claims (12)
    [1]
    A system for measuring and recording the amount of liquid in an absorbent material, for example a filler (24) in a diaper (17; 35; 49), said system comprising a sensor (1) comprising an outer electrode (3; 19 ; 36; 50) and an inner electrode (5; 22; 39; 53) arranged in or around the absorbent material and a transmitter (10; 28; 43; 58) arranged to apply an alternating voltage between the two electrodes, simultaneously measure the capacitance between the two electrodes and calculate the status of the amount of liquid in the absorbent material based on the measured capacitance.
    [2]
    The system of claim 1, wherein the sensor further comprises a surface arranged to be in electrical contact (13; 31; 42) with the body of a person, and the transmitter is further arranged to be able to apply an alternating voltage between the interior electrode and this surface, simultaneously measuring the capacitance between the sensor's internal electrode and this body, and calculate the status of the presence of a substance, for example, faeces, between the inner electrode and the body based on the measured capacitance.
    [3]
    The system of claim 1, wherein the sensor further comprises a surface arranged to be in electrical contact (13; 31; 42) with the body of a person and the transmitter further arranged to measure an ohmic resistance between it. inner electrode and this surface and calculate the status of the presence of a substance, for example, faeces, between the inner electrode and the body based on the measured resistance.
    [4]
    The system of claim 2 or 3, wherein a temperature meter is arranged in connection with the surface arranged to be in electrical contact with the body of a person.
    [5]
    A system according to any one of the preceding claims, wherein the transmitter is further arranged to be able to transmit signals representative of the calculated statuses wirelessly to one or more monitoring stations.
    [6]
    System according to any one of the preceding claims, wherein the transmitter is equipped with a gyroscope and / or an accelerometer.
    [7]
    A system according to any one of the preceding claims, wherein the signal representative of the amount of liquid in the filler represents an absolute amount of liquid, e.g. 300 ml.
    [8]
    The system of any one of claims 1-6, wherein the signal representative of the amount of liquid in the filler represents a relative amount of liquid, e.g. 20% of the total capacity of the absorbent material.
    [9]
    A system according to any one of the preceding claims, wherein the sensor is located externally on a diaper with the outer electrode and the inner electrode located outside the outward and inward facing surfaces of the diaper.
    [10]
    A system according to any one of claims 1-8, wherein the sensor is located internally in a diaper with the outer electrode and the inner electrode between the outward and inward facing surfaces of the diaper.
    [11]
    A method for measuring and recording the amount of liquid in an absorbent material, for example a filler (24) in a diaper (17; 35; 49), comprising the steps of: applying an alternating voltage between two electrodes which is arranged in or around the absorbent material, simultaneously measuring the capacitance between the two electrodes, and calculating the status of the amount of liquid in the absorbent material on the basis of the measured capacitance.
    [12]
    The method of claim 11, further comprising the steps of: applying an alternating voltage between an electrode and a surface in electrical contact with the body of a person, simultaneously measuring the capacitance between the electrode and that surface, and - calculating the status of the presence. of a substance, for example, faeces, between the inner electrode and the body based on the measured capacitance.
    类似技术:
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    同族专利:
    公开号 | 公开日
    JP6545673B2|2019-07-17|
    US20160374868A1|2016-12-29|
    JP2016524161A|2016-08-12|
    CN105392456B|2020-03-10|
    EP3019132A1|2016-05-18|
    WO2015003712A1|2015-01-15|
    CA2918109A1|2015-01-15|
    AU2014289720B2|2018-10-11|
    CN105392456A|2016-03-09|
    AU2014289720A1|2015-12-24|
    DK178086B1|2015-05-11|
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    法律状态:
    优先权:
    申请号 | 申请日 | 专利标题
    DKPA201300425A|DK178086B1|2013-07-12|2013-07-12|System for measuring the amount of urine and faeces in a diaper|
    DK201300425|2013-07-12|DKPA201300425A| DK178086B1|2013-07-12|2013-07-12|System for measuring the amount of urine and faeces in a diaper|
    CA2918109A| CA2918109A1|2013-07-12|2014-07-03|System for measuring the quantity of urine and detecting the presence of faeces in a nappy|
    PCT/DK2014/050199| WO2015003712A1|2013-07-12|2014-07-03|System for measuring the quantity of urine and detecting the presence of faeces in a nappy|
    AU2014289720A| AU2014289720B2|2013-07-12|2014-07-03|System for measuring the quantity of urine and detecting the presence of faeces in a nappy|
    CN201480037948.2A| CN105392456B|2013-07-12|2014-07-03|System for measuring the amount of urine and detecting the presence of feces in a diaper|
    EP14739661.8A| EP3019132A1|2013-07-12|2014-07-03|System for measuring the quantity of urine and detecting the presence of faeces in a nappy|
    JP2016524688A| JP6545673B2|2013-07-12|2014-07-03|System for measuring the amount of urine in diapers and detecting stools present|
    US14/903,456| US20160374868A1|2013-07-12|2014-07-03|System for Measuring the Quantity of Urine and Detecting the Presence of Faeces in a Nappy|
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