absorbent article for absorbing liquid and system discharges

专利摘要:
tool for analyzing liquid discharge data on an absorbent article, an absorbent article adapted for collecting liquid discharge data and a control unit for interacting with the absorbent article to collect liquid discharge data the invention refers to to an absorbent article for absorbing liquid discharges (eg, urine, menstrual or fecal fluid) when used in the crotch area of a user's body. the absorbent article comprises a plurality of detection zones for detecting the discharge of liquid. each detection zone is provided by first and second electrically conductive paths that are electrically isolated from each other and arranged so that a discharge of liquid between the first and second conductive paths allows electric current to flow between the first and second paths conductive, which is capable of being detected to detect the presence of liquid discharge in the respective zone. the plurality of zones are distributed longitudinally with respect to the absorbent article along an absorbent core of the absorbent article, to allow the longitudinal extent of the discharge to be determined. the first and second conductive paths are longitudinally spaced from each other. the first and second conductive paths are elongated and transversely aligned.
公开号:BR112013016174B1
申请号:R112013016174
申请日:2011-12-20
公开日:2020-06-09
发明作者:Mattias Bosaeus；Allan Elfström
申请人:Essity Hygiene & Health Ab；Sca Hygiene Prod Ab；
IPC主号:

专利说明:

“ABSORBENT ARTICLE FOR THE ABSORPTION OF LIQUID AND SYSTEM DISCHARGES”
Field of the Invention
[001] The present invention relates to an absorbent article which includes means for detecting liquid discharge. In addition, the present invention relates to a control unit for interrogating the liquid discharge detection means to obtain the liquid discharge data for the absorbent article and also to obtain data relating to the conditions of use. In addition, the present invention relates to an analysis tool that uses data from the control unit to analyze the liquid discharge performance of the absorbent article, among other analytical operations.
Background of the Invention
[002] It is known in the state of the art to provide an absorbent article with liquid discharge detection sensors. Such an absorbent article is known from patent publication AU-B-63393/94. The absorbent article according to this previous publication has a sensor mounted on it that is able to determine when urination occurred. The absorbent article is equipped with a signal transmitter so that a nursing station, in the event of urination, allows a nurse to take action (that is, replace the wet absorbent article with a dry one). The system also allows the urination time to be recorded so that urine patterns are monitored for a given patient.
Brief description of the invention
[003] The present invention aims to provide data that are not only indicative of when an absorbent article has been wetted (ie subjected to a liquid discharge), but also to allow an analysis of the performance of the absorbent article to absorb the liquid discharge, good
Petition 870190119101, of 11/18/2019, p. 12/95
2/35 how to allow the patient's diagnostic information to be obtained (for example, what type of incontinence the patient may have). In order to achieve the objective, the present invention offers an improved liquid discharge detection arrangement that allows liquid discharge propagation information to be obtained. The present invention furthermore offers to record or obtain more useful data to perform an analysis of the performance of the absorbent article and user diagnostic information. In addition, the present invention reveals ways to use the data to analyze the performance of the absorbent article or the user's diagnosis.
[004] The present invention is, in one aspect, a system concerning the absorbent article, in which the determination of the extent and / or location of urination (or perhaps fecal or menstrual matter) is enabled.
[005] In one aspect of the present invention, an absorbent article is provided for absorbing liquid discharge (i.e., urine, menstrual or fecal fluid) when used in the crotch region of a user's body, the absorbent article comprising a plurality of detection zones for detecting the discharge of liquid, each detection zone provided with at least the first and second electrically conductive paths that are electrically isolated from each other, and arranged so that a discharge of liquid between the first and second paths conductive allows the electric current to flow between the first and second conductive paths, which is capable of being detected to detect the presence of liquid discharge in the respective zone, in which the plurality of zones is longitudinally and / or laterally distributed to allow that the longitudinal and / or lateral extent of the discharge is checked. In use, a conductive bridge is formed between the first and the second conductive paths, otherwise electrically isolated, through the discharge of absorbed liquids in the absorbent core. Liquid detection is feasible by measuring a change in
Petition 870190119101, of 11/18/2019, p. 13/95
3/35 electrical property of any electrical current flowing between the first and second conductive paths, such as conductance, resistance, impedance or input capacitance.
[006] The absorbent article thus has a distribution of isolated conductive paths, which allows the detection of urination between two of them. Thus, it is possible to determine the propagation of the liquid in the absorbent article by activating a detection zone, because the discharge of liquid will cause a short circuit between two of the conductive paths, said short circuit that can be detected. The spread of the liquid discharge is indicative of the volume of liquid discharge, which is a useful parameter to be known when analyzing the absorption efficiency of an absorbent article. Longitudinal spread over time of a liquid discharge provides a good indication of separate instances of liquid discharge.
[007] In a preferred embodiment, the detection zones are distributed longitudinally in relation to the absorbent article, so that the longitudinal extent of a discharge can be reasonably matched with the volume of discharge in relation to the lateral spread.
[008] Preferably, the first and second conductive paths are spaced longitudinally from each other.
[009] More preferably, in an absorbent article comprising a top sheet to allow liquid discharge to enter the absorbent article, a back sheet to prevent liquid discharge from leaking from the absorbent article and an absorbent core captured between them, zones are distributed over at least 30% of the longitudinal extent of the absorbent core, preferably at least 40%, preferably at least 50%, preferably at least 60%, preferably at least 70% and preferably at least 80%. The longitudinal extent of the absorbent core must be understood in relation to the totality of absorbent layers
Petition 870190119101, of 11/18/2019, p. 14/95
4/35 (if there is more than one).
[0010] Preferably, the first and second conductive paths are elongated and are laterally aligned.
[0011] For an effective discharge volume detection system, preferably, there are at least three, four, five, six, seven, eight, nine, ten, eleven, twelve, fifteen, twenty, thirty or even fifty zones detection. The greater the number of existing zones, the more precisely the spread of liquid discharge can be determined. This is counterbalanced by the disadvantage of increasing the number of conductive paths, increasing the number of connections to a control unit and increasing the signal processing needs of the controller. In a preferred embodiment, there are 4 to 12, preferably 9, detection zones.
[0012] In the context of an absorbent article comprising a backsheet to prevent the discharge of liquid from leaking from the back of the absorbent article and a top sheet to allow the discharge of liquid to enter the absorbent article, and that together capture an absorbent core, the first and second conductive paths preferably extend laterally at least about 50% of the total length of the absorbent core, preferably at least about 60%, preferably at least about 70%, preferably at least about 80% and preferably at least about 90%. The lateral extension of the first and second conductive paths means that even off-center liquid discharge can be determined reliably.
[0013] In a preferred embodiment, the first and second conductive paths are in conductive contact with a respective conductive section isolated from an absorbent core of the absorbent article, where the first and second conductive paths are in electrical contact with the absorbent core. . The respective conductive section is preferably arranged
Petition 870190119101, of 11/18/2019, p. 15/95
5/35 to provide a connection from a contact area of the absorbent article control unit to the respective conductive path. The conductive sections can be isolated from the absorbent core by an insulating layer or because they are spaced from the absorbent core. In a preferred construction, the conductive sections are arranged on one side of an electrically insulating layer of the absorbent article and the conductive paths are arranged on the other side of the layer which must be in electrical contact with the absorbent core. The first and the second conductive paths can pass through the insulating layer.
[0014] In one embodiment, the contact area of the control unit is located at the bottom of the absorbent article, preferably as a protruding strip.
[0015] In this way, the conductive paths are in permanent electrical contact with the absorbent core, while the connections are isolated from them. In addition to the insulating layer, the connections and conductive paths can otherwise be a unitary conductive path.
[0016] In one embodiment, conductive material (e.g. metal) bathed polymer fibers are used as first and second conductive paths and / or as bonds, such as silver-plated nylon threads. Alternatively, conductive wires, such as stainless steel, can be used.
[0017] In one embodiment, the insulating layer is a backing sheet of the absorbent article made of liquid impermeable material.
[0018] In one embodiment, the connections are oriented longitudinally and the conductive paths are oriented laterally. The conductive paths oriented laterally are longitudinally spaced from each other.
[0019] Preferably, one of the first and the second
Petition 870190119101, of 11/18/2019, p. 16/95
6/35 conductive paths and shared between two detection zones, thus allowing a reduction in the number of conductive paths and, therefore, the number of connections to a controller.
[0020] In a preferred embodiment, the first and second conductive paths are positioned below a top surface of an absorbent core of the absorbent article. In this way, the conductive paths could be incorporated into the absorbent core or positioned below the absorbent core. The conductive paths are preferably positioned under the absorbent core, and still in electrical contact with them. Embedding the paths in the core tends to reduce the sensitivity of the motion sensor, while the location of the paths between the core and a backing sheet of the absorbent article provides an improved sensitivity of liquid discharge. In one embodiment, the absorbent core can be made of a lower layer of an absorbent core material and an upper layer of absorbent core material that is smaller in size when the absorbent article is viewed in plan and placed flat. Alternatively, the lower layer may have a different composition of absorbent materials, for example, the proportion of superabsorbent in relation to the fluff different from that of the upper layer. In both cases, the first and second conductive paths can be located between the upper and lower layers of the absorbent core.
[0021] The first and second conductive paths can be sewn to the absorbent article, passing through a back sheet of the absorbent article.
[0022] In a preferred embodiment, the article is an incontinence diaper for adults and the paths are longitudinally spaced by a distance of 3 cm to 8 cm, preferably 3 to 6 cm, preferably 4 to 5 cm, and are paths adjacent conductive conductors, which provides an ideal
Petition 870190119101, of 11/18/2019, p. 17/95
7/35 between covering a total longitudinal extension of the absorbent core, reducing the number of connections and contacts required, and ensuring a sufficiently dense dispersion of detection zones to detect a first, or low volume of liquid discharge.
[0023] In one embodiment, there are at least three conductive paths providing at least two detection zones, in which the conductive paths are uniformly distributed throughout the absorbent core.
[0024] In one embodiment, each detection zone is formed by adjacent conductive paths.
[0025] In a preferred embodiment, a system is provided comprising the absorbent article described above and a control unit, in which the control unit is configured to measure an electrical property between the first and second conductive paths to allow detection of when the discharge of liquid is present between the first and second conductive paths and to do this for each of the plurality of detection zones.
[0026] The control unit is configured to apply an electrical potential between the first and the second conductive paths and determine the electrical property from any current returned.
[0027] The controller is thus able to detect which, if any, of the zones is the discharge of liquid, which will be an indication of the dispersion of liquid discharge and, therefore, also the volume of liquid discharge.
[0028] Preferably, the control unit is configured to measure the plurality of zones sequentially to avoid interference between each measurement and to simplify the switching structure on the control unit.
Petition 870190119101, of 11/18/2019, p. 18/95
8/35
[0029] Preferably, the control unit is configured to apply a pulse of electrical energy in each zone and to perform the impedance measurement, using the pulse. The pulse can be on the order of 1/10 of a second or less. An electrical energy pulse is one that is applied in discrete bursts of electrical energy separated by a time of rest, when compared to the continuous use of energy. Thus, the control unit can switch on the application of voltage between the conductive paths for a limited amount of time and switch it off for a long period of time between times.
[0030] Preferably, it is not only the presence or absence of a conductive path existing between the first and second conductive paths, but an indicator of the degree of electrical conductance that is measured (for example, an impedance measurement). The degree of conductance is indicative of how close the absorbent article is to saturation in that zone, which allows a better estimate of the volume of liquid discharge. Thus, the measured electrical property is preferably one that changes in size or length depending on the amount of liquid that exists between the first and the second conductive paths, as a result of the impedance or resistance to the electric current that passes through the absorbent core, between the first and the second conductive pathways decreasing with increasing humidity (the degree of variation of the electrical property with the amount of liquid discharge can significantly reduce towards the saturation of the core).
[0031] In a second aspect of the present invention, an absorbent article is provided for absorbing liquid discharges from a user, when used in the crotch area of the user, the absorbent article comprising a first and a second electrically conductive path that are electrically isolated from each other and which are arranged along a periphery of the absorbent article, in such a way that the discharge of liquid from the user that spreads to be between the first and second paths
Petition 870190119101, of 11/18/2019, p. 19/95
Conductive 9/35 provides a conductive path between them, which allows leak detection.
[0032] The absorbent article above allows leak detection since any discharge of liquid that reaches the periphery of the absorbent article is indicative of a leak in the article.
[0033] Preferably, the first and second conductive paths are positioned peripherally outside an absorbent core of the absorbent article when the absorbent article is seen in the flat state, when placed flat. This thus provides an indication that the liquid discharge expands beyond the absorbent core, which is indicative of a leak in the article.
[0034] Preferably, the absorbent article has a first and a second side edge shaped to fit the legs of a user and the first and second conductive paths are arranged along at least one of the side edges that is on the groin or leg region of the absorbent article, where the leak detection functionality is considered most effective.
[0035] Preferably, the first and second conductive paths are positioned along an elastic leg portion of the absorbent article on at least one side of the absorbent article.
[0036] In a preferred embodiment, a system is provided that comprises a control unit and the absorbent article described above, in which the control unit is configured to apply a potential between the first and second conductive paths and measure an electrical property between them to allow the determination of whether liquid discharge has spread to a position between the first and the second conductive paths.
[0037] In a preferred embodiment, the system comprises an analysis module configured to compare the measured electrical property with
Petition 870190119101, of 11/18/2019, p. 20/95
10/35 a predetermined limit and make a determination that a leakage state of the absorbent article will have been reached if the predetermined limit has been exceeded, where the predetermined limit is set to distinguish about conductance between the first and second conductive paths as a result of electrical conduction through the user's skin or through moisture in the user's skin in relation to saturation as a result of leaks from liquid discharge.
[0038] In yet another aspect of the invention, an absorbent article analysis system is provided which comprises an absorbent article for absorbing a user's liquid discharge when used in the user's crotch zone and a position sensor, which is capable of to emit a position signal that allows the differentiation between a lying position and a seated position of the user, a liquid discharge detector that is capable of emitting a liquid discharge signal indicative of a moisture state of the absorbent article, in which an analysis module is configured to record the position output signal and the liquid discharge signal in order to correlate the position signal and the liquid discharge signal over time.
[0039] The analysis system thus allows the analysis of time patterns when liquid discharge occurs and also any pattern in terms of liquid discharge as a result of movement or change of position. The analysis system is particularly useful in the diagnosis of stress urinary incontinence, as it can be determined that a change from lying to standing position occurred at approximately the same time as a liquid discharge event, which could be considered as indicative of a user having stress incontinence.
[0040] The position sensor is preferably supplied as
Petition 870190119101, of 11/18/2019, p. 21/95
11/35 part of a control unit connected to the absorbent article. Preferably, the position sensor is arranged in a frontal region of the waist of the absorbent article, preferably so as to be generally centrally located in relation to the user's torso. It has been found that arranging the position sensor on the front of the absorbent article allows a strong signal of movement related to the user to be obtained. Preferably, the position sensor is an accelerometer. An accelerometer or other appropriate position sensor is configured to emit a signal that it is able to differentiate between the user's lying, sitting, standing and moving states, which is useful information in determining the voiding patterns for a user and useful as a diagnostic tool. The position sensor is preferably also configured to output the output signal in such a way that the position of a plurality of orientations of a person lying down can be differentiated, including at least one lying position in the supine, ventral, left or left position. right side.
[0041] The analysis tool is preferably configured to transmit a parameter indicating a user's mobility based on the amount of time the user is determined to be in a state in which he is, perhaps, compared to a sitting or lying.
[0042] In another preferred embodiment, the liquid detector comprises a plurality of liquid discharge detection sensors, so that the analysis module records the wetting state in a plurality of detection zones distributed on the absorbent article. The system thus allows the discharge of liquid to be measured in a number of positions in the absorbent article, perhaps in conjunction with the determination of a position in a series of different user positions correlated against the timing of the various events, which provides highly useful data on the performance of the absorbent article as well as diagnostic information
Petition 870190119101, of 11/18/2019, p. 22/95
12/35 useful about the user.
[0043] The use of a certain number of detection zones allows the spread of liquid discharge to be tracked over time. Preferably, an output module is configured to produce a display of the spread of the liquid discharge over time. The detection zones are preferably distributed longitudinally in relation to each other, preferably over at least 50%, 60%, 70%, 80% and 90% of a total longitudinal extension of the absorbent core of the absorbent article, when viewed in plan, with the absorbent article placed flat.
[0044] In addition, the system allows the differentiation of a first event and at least one subsequent liquid discharge event based on the change in the number of zones that are determined to be wet or based on a change of electrical property in a given zone, indicating an increase in humidity detected by the corresponding liquid discharge sensor.
[0045] Preferably, the liquid detector comprises a measurement module that is configured to measure an electrical property (for example, impedance) of a detection sensor indicating the degree of humidity in a given liquid discharge detection zone, so that the analysis module is able to record the degree of wetness for a given liquid discharge detection zone or a plurality of liquid discharge detection zones. In this way, not only can the presence of liquid or otherwise be determined, but also how the area is wetted, which provides useful analysis information.
[0046] In a preferred embodiment, an output module is configured to display output information showing the electrical property measured over time (which indicates the events of liquid discharge and, perhaps, also the degree of liquid discharge), preferably, respectively,
Petition 870190119101, of 11/18/2019, p. 23/95
13/35 for each determined zone and preferably also including position data differentiating, for example, lying and standing positions and at what time, and even more, preferably the leak data showing the occurrence of a leak event and at what time. Preferably, the output module is configured to transmit a parameter indicative of a liquid discharge volume calculation performed by the analysis module. The output module can display the information on a light emitting screen, such as a print or in other known ways.
[0047] In a preferred embodiment, data from the output signals are stored in a physical memory with the associated time. The use of a physical memory device means that it is not necessary for the system to be provided with data transmitters for each absorbent article and a receiver in each location where the system is configured. Instead, the absorbent article can be provided with a control unit mounted on it and having, as part of the control unit, physical memory, thus providing a system with reduced installation complexity. The analysis software can retrieve the data from the physical memory and perform analytical operations on it.
[0048] Preferably, the correlation is made over time in relation to a 24-hour clock in local time, so that it can be elaborated when liquid discharge occurs and the carrier's positions in relation to local time. This can be useful since, for example, if the discharge of liquid occurs at night or during the day is interesting.
[0049] In a preferred embodiment, the analysis module is configured to determine a saturation condition of the liquid detection zone from the measured electrical property and calculate a liquid discharge volume from the number of liquid detection zones saturated. It was found that this method of detecting discharge volume of
Petition 870190119101, of 11/18/2019, p. 24/95
14/35 liquid is particularly accurate, compared to other tried methods.
[0050] Preferably, the system further comprises a leak detector that is configured to emit a leak signal indicating a leak from the sides or ends of the absorbent article and the analysis module is configured to correlate the position signal, the liquid discharge detection signal and the leak signal over time, thus the system is able to provide useful information about the causes of leakage of the absorbent article, which can prove useful to evaluate the performance of the article pad.
[0051] In one embodiment, each of the signals, that is, liquid discharge, position, etc., is generated and recorded at regular intervals.
[0052] In another aspect of the present invention, there is provided a system comprising a control unit and an absorbent article, the absorbent article for absorbing a user's liquid discharge when the absorbent article is used in the user's crotch zone , the absorbent article comprising a liquid discharge sensor which detects the discharge of liquid from a change in an electrical property when the absorbent article is wetted, wherein the control unit is configured to subject the liquid discharge sensor to pulses of electrical energy in order to take measurements of electrical property in each pulse, in which the pulses are separated by a resting period of electrical energy.
[0053] The electrical property can be measured using an oscilloscope, multimeter, voltage divider or other known means.
[0054] The pulsed operation of the system has at least two advantages. A first advantage is that it saves battery power, compared to a constant voltage applied to the sensor. The period of
Petition 870190119101, of 11/18/2019, p. 25/95
15/35 rest between the wrists is effectively a battery suspension mode. A second advantage is that it has been found that the measurement of electrical property under the extended application of current can lead to irregular measurements on a wet absorbent article.
[0055] Preferably, the control unit comprises a battery from which the pulsed electrical current is extracted. Preferably, the control unit is mounted on the absorbent article.
[0056] Battery life is particularly important in the present system, as it is necessary to work over a test period, if the testing of absorbent articles is to be implemented properly.
[0057] In another embodiment, the absorbent article comprises a plurality of liquid discharge sensors of this type and the control unit is configured to apply a pulse of electrical energy to each of them, preferably in sequence, in order to determine the electrical property of each liquid discharge sensor.
[0058] The sequential processing of each sensor avoids interference. In one embodiment, there are at least 3, 4, 5, 6 or more of such sensors, and the control unit is configured to apply energy pulses to each of them in a sequence that prevents adjacent pulses in time from being applied to the adjacent sensors in space. In one embodiment, each sensor is provided by the first and second adjacent conductive paths which are electrically isolated when the absorbent core is dry and which has a conductive bridge between them extending through the absorbent core when the absorbent core is wet. In a preferred embodiment, the adjacent sensors share the intermediate conductive path as one of the first and second conductive paths. In one embodiment, the control unit is configured to apply a
Petition 870190119101, of 11/18/2019, p. 26/95
16/35 first pulse between the first and second adjacent conductive paths of a first sensor and to apply a subsequent pulse between the first and second adjacent conductive paths of a second non-adjacent sensor. Alternatively placed, the second sensor and the first sensor are located with at least one sensor intermediate between them. This sequencing algorithm avoids interference between the results of subsequent pulses, which is also aided by the natural time interval between pulses.
[0059] Preferably, the energy pulses are pulses of alternating current or direct current. The pulses can take the form of short bursts of energy, separated by longer periods of rest or more intense forms of energy pulses.
[0060] The control unit may comprise a physical memory device, in which the measured electrical property is preferably stored in association with time, in a preferred embodiment, the control unit comprises a buffer and the memory unit The control is configured to store a plurality of sequential electrical property measurements for a given liquid discharge sensor. Data storage in the buffer and physical memory is powered by the battery. This allows for battery savings as buffer storage uses significantly less energy than storage in physical memory.
[0061] It is also preferred that the pulses of electrical energy are not generated until the control unit has been brought into contact with a liquid discharge sensor contact. Thus, until the control unit is mounted on the absorbent article and properly electrically contacted with it, the control unit is maintained in a low-power mode.
Petition 870190119101, of 11/18/2019, p. 27/95
17/35
[0062] An application of this feature would be to have a contact in the absorbent article that acts as a switch for the control unit when the contacts of the control unit are put in electrical coupling with the contacts of the absorbent article.
[0063] In yet another aspect of the present invention, an absorbent article is provided for absorbing a user's liquid discharge when the absorbent article is used in the crotch area of a user, the absorbent article comprising a front sheet for transferring the discharge of liquid into the absorbent article, a backsheet to prevent leakage of liquid discharge from the absorbent article and an absorbent core to absorb the discharge of liquid and which is trapped between the front sheet and the backsheet, wherein the absorbent article comprises at least one liquid discharge detection sensor to detect a wet condition of the absorbent article based on an electrical property associated with the detection sensor and the absorbent core, wherein the absorbent core has a Hardy integrity of at least 5 stocked, at least 10 stocked, at least 20 stocked, at least 30 stocked, at least 50 stocked, at least 60 stocked at least 70 stores, at least 80 stores, or at least 90 stores. Hardy's integrity test procedure to be used to assess the scope of this statement is described below.
[0064] It has been found that the reliable results of liquid discharge detection are dependent on the high integrity of the absorbent core. It is speculated that during use, a low integrity absorbent core will partially break when wet causing breaks in the conductivity of the core, preventing or reducing the accuracy of the measurement of electrical property.
[0065] Preferably, the liquid discharge detection sensor includes first and second electrically insulated conductive paths and
Petition 870190119101, of 11/18/2019, p. 28/95
18/35 is operable by passing electric current between the first and the second conductive paths through the absorbent core, when the absorbent core is wet and to measure the electrical property from the electric current passed in this way.
Brief description of the Figures
[0066] Figure 1 shows a plan view of an absorbent article arranged flat and illustrates a preferred arrangement of liquid discharge detection lines in longitudinally spaced side lines.
[0067] Figure 2a describes an absorbent article with an emphasized leak detection mechanism instead of a liquid discharge detection mechanism, as in Figure 1.
[0068] Figure 2b is a conceptual diagram that illustrates the placement of leak detector wires in greater detail with respect to the elastics for the legs.
Detailed description of the invention
Absorbent article and liquid discharge sensor device
[0069] Figure 1 shows an absorbent article (1), which generally comprises a top sheet, a back sheet and an absorbent core captured between the same two. The absorbent article (1) is shown in the form of a diaper for incontinent adults in Figure 1. The principles of the present invention are, however, applicable to other absorbent articles such as baby or child diapers, Intimate pads or other absorbent articles known. The absorbent article (1) is an example of a conventional adult incontinence diaper except for the presence of a plurality of liquid discharge detection zones (4) (in this specific example, there are five liquid discharge detection zones ( 4)).
[0070] The zones (4) are distributed longitudinally over about 50% of the total longitudinal extension of the absorbent core (2). The position
Petition 870190119101, of 11/18/2019, p. 29/95
19/35 longitudinal zone (4) is moved more towards the front region of the absorbent article than from a posterior region, in order to be more likely to receive any urination directly. The zones (4) extend laterally for about 60% of the total lateral width of the absorbent core (2) for the zones (4) more front and rear and about 80% for the zone (4) located closer to the laterally thinner point of the absorbent core.
[0071] Each zone (4) comprises first and second electrically conductive paths (6) (in the form of electrically conductive wires), which are each aligned with the transverse axis (8) of the absorbent article (1), and are longitudinally spaced from each other along the longitudinal axis (10) of the absorbent article. The conductive paths (6) are in physical and electrical contact with the absorbent core (2). The end zones (4) share a conductive wire (6) with an adjacent zone, while the intermediate zones (4) both share the conductive wires (6) with their adjacent zones (4).
[0072] The absorbent article includes (1) a contact area of the control unit (12) in which a control unit will be connected in order to activate each of the zones (4) to obtain a liquid discharge reading. The contact area (12) is located in the frontal region of the waist transversely central of the absorbent article. The contact area (12) includes a plurality of electrical contacts (14) for making electrical contact with the corresponding contacts on the control unit. Each conductive path (6) is connected to a respective electrical contact (14) by means of a respective electrically conductive connection (16). The combination of a particular contact (14), a connection (16) and a conductive path (6) is formed by a unitary structure (a conductive wire) in the preferred embodiment, as will be explained below. The connections (16) extend along the shortest path from the conductive path (6) to the corresponding contact (14). Although not shown, the contact surface (12) preferably includes a blind contact that
Petition 870190119101, of 11/18/2019, p. 30/95
20/35 the control unit is configured to detect, to determine an “on” or “mounted to the absorbent article” condition.
[0073] The conductive path (6) can be distinguished from the connection (16) because the conductive path (6) is in direct physical and electrical contact with the absorbent core (2), while the connection (16) is not so that it can be electrically isolated from the absorbent core (2). More specifically, the conductive paths (6) are on the side facing the absorbent core of the backsheet and in electrical and physical contact with the absorbent core (2). The connections (16) are located on the other side of the backsheet so that the backsheet offers electrical insulation between the absorbent core (2) and the connections (16). A liquid-impermeable or hydrophobic cover sheet is placed over the connections (16) on the outside of the back sheet, in order to avoid erroneous readings for detecting liquid discharge as a result of the outside of the absorbent article (1) coming into contact with humidity (for example, due to the user sitting on a damp surface). The connections (16) pass through the backsheet at the points (20). One end of each conductive path (6) ends without a return path to the contact area (12). Thus, a return path can only be established by passing current from a contact (14) through a connection (16) and a conductive circuit (6) and returning through an adjacent conductive path (6) and its connection (16) by passing current through a space between adjacent conductive paths (6) as a result of the absorbent core having become moistened in space.
[0074] In the preferred embodiment, each contact (14), connection (16) and conductive path (6) is made of a single wire that has been coated with electrically conductive material (for example, metal or carbon or conductive polymers).
[0075] The absorbent article (1) can be made by taking an article
Petition 870190119101, of 11/18/2019, p. 31/95
21/35 conventional absorbent, such as a Tena Flex Medio (super absorbency level), which is commercially available, and modify it to include the coated yarns. More specifically, a needle with a thread attached to it is pierced through the backsheet of the absorbent article (1), so that a part of the thread is located on one side of the backsheet to provide the conductive path (6) in communication electrical with the absorbent core (2) and another part is located on the other side of the backsheet to provide the connection (16). The conductive path part (6) is glued according to the extent transversely aligned with one end of the wire terminating at one end of the conductive path, as shown in Figure 1. The connecting part (16) of the wire is glued in place on the sequence of the extension shown in Figure 1, in order to extend to the edge of the frontal waist and slightly beyond it. This process is repeated for each conductive segment. A cover sheet (18) is laminated over the threads (16) and the outside of the back sheet to hold the threads in place and provide a liquid barrier. A tab of adhesive tape protruding beyond the front edge of the waist is used to secure the ends of the conductive wire contact terminals in the contact area (12).
Leak detection
[0076] In Figure 2a, an absorbent article (1) in a flat configuration is shown. The absorbent article (1) has first and second conductive paths (24) for leak detection, which extend around a periphery of the absorbent article (1). The conductive paths (24) follow the path of each other, but are slightly apart so that an electrically conductive path is established between them only when a discharge of liquid is in the space between them. in the specific configuration shown, the conductive paths (24) extend around three sides of the absorbent core (2) to provide an edge around the core
Petition 870190119101, of 11/18/2019, p. 32/95
22/35 absorbent (2). The conductive paths (24) are arranged peripherally outside the absorbent core (2) and also outside the raised barriers (26) of the absorbent article (1). The conductive paths (24) follow the leg elastics (22) and are laterally arranged in the same location as the leg elastics (22). In Figure 2b, it can be seen that the conductive paths (24) are arranged with three intermittent elastic legs (22).
[0077] The conductive paths (24) end at one end in the contact zone (12) (not shown in Figure 2 - See Figure 1), then extend along the elastics of the left legs (24), around on the posterior waist side of the absorbent core (2), they extend along the right leg elastics (24) and finally end in the front waist region of the absorbent article (1). The contact termination of the conductive paths (24) in the contact area (12) offers a pair of contacts to contact the corresponding contacts in the control unit.
[0078] The conductive paths (24) are positioned between the layers between which the leg bands (22) are sandwiched. This is done by threading a thread connected to a needle in order to pierce the layers. In order to avoid erroneous leak detection by impedance readings as a result of external humidity, a liquid-impermeable covering layer is placed and an addendum on the outer layer to cover the conductive paths (24).
Control Unit
[0079] The control unit of a preferred embodiment of the present invention will now be described without reference to a Figure that reveals the preferred structural form of the control unit. The control unit includes contacts to engage with the contacts (14) on the tab protruding from the absorbent article tape (1). The control unit has a main housing with teeth protruding from the housing to interact with the contact wires (14) of the
Petition 870190119101, of 11/18/2019, p. 33/95
23/35 absorbent article (1). The teeth thus provide the contacts of the control unit.
[0080] The control unit includes a memory card to provide physical memory, a buffer memory, an impedance measurement circuit, an accelerometer, a clock, a processor and a battery. The battery is used for powering all components of the control unit. The elements of the listed control unit are preferably stored in a housing that can be opened and closed. The housing preferably has a respective fastener, such as a hook fastener (i.e. the Velcro hook component FTM), to fix it to an external cover of the absorbent article (1). The control unit is designed to be mounted centrally in a frontal region of the waist of the absorbent article (1). The control unit is configured to maintain only power circuits that cannot be switched off before the control unit is contacted with the contacts (14) of the absorbent article. More specifically, the control unit is in a mode where only essential circuits are kept powered until the blind contact of the absorbent article is detected. Thus, the watch must be kept powered even before the control unit is mounted on the absorbent article, but the impedance measurement or the accelerometer circuit (discussed below) does not need to be supplied with power at this time. The connection of the contacts of the control unit to the contacts (14) of the absorbent article (1) acts as a switch to enter an active operating state, so that, for example, the impedance measuring circuit is supplied. This is a battery saving feature.
[0081] The accelerometer is configured to emit a different signal, depending on whether the user of the combination of control unit and absorbent article (1) is lying down, sitting or standing. The accelerometer can
Petition 870190119101, of 11/18/2019, p. 34/95
24/35 also emit a different signal, depending on whether the user is lying supine, ventral, left or right lateral, or is active for a period of time, for example, walking.
[0082] The impedance measurement circuit is configured to regularly apply a potential between the adjacent pairs of conductive paths (6) of the absorbent article (1) and an impedance measure or indicator between them. In general, the lower the impedance measurement, the wetter the absorbent core is. The responsiveness of the absorbent core (2) to wetting when the absorbent core (2) reaches saturation between the adjacent conductive paths (6) is significantly less than when the absorbent core (2) is only slightly moistened. The impedance measurement circuit applies the potential between pairs of adjacent conductive paths (6) sequentially. To do this, the impedance measurement circuit switches between pairs of contacts (14), until a measurement of impedance or other electrical properties between the conductive paths (6) that changes depending on the core wetting has been performed to the complete set of adjacent pairs of conductive paths (6). In order to save the battery resource, there is a rest time between the potential to be applied to each pair, which is greater than the duration of the electrical potential application, thus activating the adjacent conductive paths (6) with pulses of electrical energy to measure impedance or other electrical property. In fact, the sum of the duration of the current pulses for each adjacent pair of conductive paths (6) has a shorter duration than the resting time between the pulses, for any adjacent pair of conductive paths (6). Examples of durations are a resting time of one second between pulses of sequential current for a given pair of adjacent conductive paths (6) less than 0.1 second to multiplex through the full complement of pairs of adjacent conductive paths (6).
Petition 870190119101, of 11/18/2019, p. 35/95
25/35
[0083] The processor is configured to perform the impedance measurements of the impedance measurement circuit and store them in the buffer until a sequence of a set of measurements for all pairs is stored in the buffer. The processor is also configured to take an accelerometer reading for each set of impedance measurements and store it in the buffer. The processor is further configured to store a clock reading with each set of accelerometer and impedance measurements. The storage of this data set is repeated regularly (for example, every second, as described above), until the buffer is full or almost full. At this time, the processor is configured to transfer the data from the buffer to register on the memory card. Buffering allows the number of memory card write operations to be reduced, which is a significant energy saving for the battery, since memory card writing is relatively energy intensive.
[0084] The memory card is removable so that the stored data can be accessed by analysis software located remotely. The stored data can alternatively be accessed by cable, a USC connection or the like, in such cases, embodiments of physical memory other than a memory card can be used.
Analysis module
[0085] An analysis module, performed by means of software, is used to process the stored data in a form useful for analyzing the performance of the absorbent article and for other purposes, such as, for diagnostic reasons. A card reader is used to retrieve the data and insert it into the analysis module and in the preferred embodiment the analysis module receives
Petition 870190119101, of 11/18/2019, p. 36/95
26/35 the data and output it to a display in a conveniently readable way. An example of an output for the analysis module is to present an impedance graph with a different color line for each of the various zones so that the degree of wetting in each zone and its evolution over time can be seen by a user of the analysis software.
[0086] The analysis module receives the impedance data for each of the areas of the memory card and rotates them through a filter to smooth the data, in order to present clear peaks for when a liquid discharge event has been carried out and to smooth out any noise attributes in the data. Impedance peaks in the graph show the moment when a liquid discharge event occurred and in which zones, and will also show how the liquid discharge spreads through the absorbent article over time. The graph will allow a user of the analysis software to determine when the initial urination occurred and also whether all subsequent liquid discharges occurred. Being able to see the spread of the liquid discharge over time is useful information to assess the absorption performance of the absorbent article. To be able to see when and how often the discharge of fluid has occurred it is useful to diagnose a particular type of incontinence such as drip incontinence and it is also useful in identifying patterns of fluid discharge, which will allow a caregiver optimize the time when an absorbent article must be replaced with a new dry absorbent article in order to minimize the amount of time the user is subjected to a wet absorbent article.
[0087] An example of how to determine individual liquid discharge events is to analyze the measurement data of electrical property measured between conductive paths that change in dependence or how wet the absorbent core is in a conductive path through the absorbent core. It was found that the electrical property, particularly the
Petition 870190119101, of 11/18/2019, p. 37/95
27/35 impedance, increases until it reaches a peak (or valleys), when the discharge of liquid is received for the first time between the first and second conductive paths and then settles. The pattern when plotted is different and relatively easily viewed. This can be as a result of increased temperatures from a recent liquid discharge to an already established one or due to its initial flow in relation to a stagnant liquid discharge. Thus, the analysis module can be configured to monitor the electrical property measured over time to determine these peaks (or valleys) to make a determination of individual liquid discharge events. Alternatively, electrical property data measured over time could be passed on to a user in such a way (for example, enough time resolution graph) for the user to establish each individual liquid discharge.
[0088] In addition to a form of graph for the data, the analysis module also allows the visualization of the spread of the liquid discharge over time by means of a graph of the absorbent article and the various zones, in which the wet zones are illustrated with a different color or shading of the dry zones and that can be traversed in time to show the progress of liquid discharge and subsequent liquid discharges in an intuitive way for the user.
[0089] The analysis module is also configured to display readings from the accelerometer and leak detection in the impedance graph as a function of time so that a user can determine the user's position of the absorbent article during the discharge of liquid, and also over the time that the absorbent article is used to determine the liquid discharge conditions and the user's standing position when the leak occurred. The accelerometer provides useful diagnostic information in conjunction with liquid discharge information, because if a liquid discharge is always
Petition 870190119101, of 11/18/2019, p. 38/95
28/35 coincident with a carrier changing his lying position to a sitting position or from a sitting position to a standing position, this is an indication that the user suffers from stress incontinence. Being able to determine the position a user is in, as well as the liquid discharge situation, when a leak occurs will be useful information to analyze the cause of a liquid discharge leak.
[0090] In order to avoid erroneous determinations of leakage of liquid discharge due to the current flow between the first and the second conductive paths through the skin, in particular through the wet skin, the analysis module compares the impedance measured in the circuit leakage with a predetermined limit and does not indicate on the graph that the leakage has occurred until the impedance is below the limit, which thus ensures that a leak is only represented when it actually occurred.
[0091] If a diaper system was created in a nursing home, the analysis module is capable of producing information relevant to the quality of care provided to users. An interesting example of statistics that the analysis module can be configured to provide is the average amount of time a user suffers from using a wet absorbent article. If the average amount of time exceeds acceptable limits, the user of the software is aware of the lack of attention being offered.
[0092] The analysis module can also be configured to produce an estimate of urine volume, which is useful for those who develop products in assessing the effectiveness of the absorbent article and useful information for a caregiver to determine if the level correct absorption of absorbent article is being used. The analysis module is configured to determine from the impedance level whether a zone
Petition 870190119101, of 11/18/2019, p. 39/95
Specific 29/35 reached the saturation point. The impedance level at which saturation occurs is a predetermined parameter of the analysis module as well as the amount of liquid at saturation. From the number of zones that have reached the saturation point, the analysis module is able to calculate an acceptably good estimate of the volume of liquid discharge. A more sophisticated estimate of the liquid discharge volume can be performed by correlating the impedance with the amount of liquid absorbed by a detection zone before, in particular, liquid saturation occurs, which can allow relatively small volumes of discharge of liquid are calculated as with a user who suffers from drip incontinence.
[0093] It is also useful to determine the length of time, particularly in a system of absorbent articles, before the first liquid discharge event occurs. The data stored on the memory card starts at zero time when the control unit first contacts the contacts of the absorbent article. The output module is thus configured to determine the time period from when data is first recorded for the absorbent article, so that the impedance measurement shows that a first liquid discharge event has occurred. The analysis module is configured to transmit this information.
Use
[0094] To use the system described above, the user receives an absorbent article (1) having liquid discharge detection zones (4) as shown in Figure 1 and conductive leak detection paths (24) as shown in Figure 2 A control unit, which is preferably minimized in size, is connected to a front region of the waist of the absorbent article (1) by means of the hook portion of conventional hook and loop fastening means so that a respective tooth of the teeth of the
Petition 870190119101, of 11/18/2019, p. 40/95
The control is engaged with a corresponding contact (14) in the contact zone (12) of the absorbent article. The absorbent article is placed in a carrier so that the control unit is able to control and record physical memory data about liquid discharge events and the user's position at any time.
[0095] As the control unit and the absorbent article are brought into contact, as described above, the impedance measurement circuit starts collecting data, just as the accelerometer does. Thus, the impedance measurement circuit of the control unit will apply for a short duration (less than a tenth of a second) an electrical potential between the first and the second conductive paths (6) of one of the liquid discharge detection zones (4) and repeat the operation for each of the liquid discharge detection zones (4) at a time. The impedance between the first and the second conductive paths (6) was each of the four detection zones is made and stored in the buffer. The impedance measurement circuit then applies a potential between the first and second conductive paths (24) of the leak detection means (again for a duration of less than 1/10 of a second) and records the data impedance values obtained in the control unit's buffer. The measurement of the accelerometer position is also made by the processor of the control unit and stored in the buffer. A rest time of the order of 1 second is then allowed to pass before the same measurements are taken again in order to record a subsequent set of data in the buffer. This process is repeated until the buffer is full and at this point a single writing step from the memory card is performed to transfer the data from the buffer to the memory card. This data collection process is repeated during the lifetime of using the control unit and the absorbent article.
Petition 870190119101, of 11/18/2019, p. 41/95
31/35
[0096] If the user is lying down, the accelerometer is able to distinguish this state in its output signal and also to distinguish whether the user is lying in supine, ventral or lateral decubitus (and perhaps also if left or right lateral).
[0097] If the user urinates, the current can flow between the first and the second conductive paths (6) of the liquid discharge detection zone (4), in which, initially, urination occurs. This will cause a change in the impedance that the control unit is able to detect and record. According to the second, while urination propagates through the liquid discharge detection zones (4), the change in impedance in the other zones (4) can be detected and recorded. Thus, the spread of urination can be determined by the analysis software as well as its speed of progress and the length of its course. If some of the detection zones (4) become saturated and there is a second urination event, zones (4) that have not yet been saturated or activated will provide an impedance change in the output signal for those zones (4), which will therefore allow the analysis software to detect a subsequent liquid discharge event.
[0098] If the discharge of liquid is able to spread beyond the absorbent core o and pass to the peripheral conductive paths (24), in order to reach the leg elastic area (22), then when a potential is applied between the first and second conductive paths (24), the impedance measurement circuit will register an impedance variation. The analysis software will be able to compare the recorded impedance between the conductive paths (24) with a predetermined limit and determine that a leak has occurred.
[0099] When the time comes to replace the absorbent article (1) with a new absorbent article, the control unit can be mounted on the new absorbent article in the manner described above. The analysis module is capable of
Petition 870190119101, of 11/18/2019, p. 42/95
32/35 to determine that the data breach occurred as a result of the control unit going to a passive state once the contacts (14) of the absorbent article (1) of the first absorbent article (1) were disconnected. The control unit has an identifier that is uniquely identifiable by the analysis module, in order to allow it to be differentiated from other control units, and if the analysis must perform a diagnostic function for the same patient, then a unit of analysis Private control, must be maintained for use with the same patient, so that all data recorded by the control unit can be associated with this patient.
[00100] When it is time to recover the data, the control unit is disassembled from the absorbent article and a memory card is removed. The memory card is placed in a memory card reader of the analysis module so that the analysis module can retrieve the data to perform data analysis operations, as described above.
Alternatives
[00101] In the embodiments indicated above, the conductive paths (6), (24) of the liquid discharge detection zones (4) and the leak detector are applied in the form of a segment that has been electrically coated with a material conductor. The conductive paths (6), (24) can instead be carried out by means of electrically conductive ink printed on the absorbent article (1) or on a support integrated with the article. The support can, instead of being printed with conductive ink, can be provided with conductive wires, which can offer advantages in terms of manufacturing efficiency, particularly when mass manufacturing.
[00102] The conductive paths (6) of the liquid discharge detection zones (4) shown in Figure 1 are straight and perfectly aligned transversely. It is important that conductive paths (6)
Petition 870190119101, of 11/18/2019, p. 43/95
33/35 extend from one side of the absorbent core adjacent to the other side of the absorbent core (2), so that a liquid discharge event is detected even if the liquid discharge is off-center or restricted to a small lateral portion of the absorbent core (2). It is envisaged that the conductive paths (6) can be wavy or straight, as shown. Alternatively, the conductive paths (6) can extend at an angle to the transverse axis (8) in order to individually define a V-shaped surface, and define, in combination with an adjacent path, a diamond shape. Many other configurations are provided for conductive paths that extend laterally (6).
[00103] The conductive paths (6) shown in Figure 1 are regularly spaced in the longitudinal direction. It is possible, however, to conduct the conductive paths so that they are more densely spaced in the longitudinal direction in an area of the absorbent core (2) that is likely to receive most of the urination.
[00104] Referring to Figure 2a, it is possible to separate the conductive paths (24) for a leak detection zone on the left side comprising first and second conductive paths and a leak detection zone on the right side comprising first and second paths conductive and having a corresponding pair of contacts in the contact area (12) for both the left and right leak detection zones. In this way, the leak detection data identifies which side of the absorbent article (1) the leak occurred.
[00105] In Figure 1, five liquid discharge detection zones (4) are represented. Other numbers can, of course, be used. An absorbent article that has 10 of the
Petition 870190119101, of 11/18/2019, p. 44/95
34/35 said liquid detection zones, for example, is conceivable.
[00106] The conductive paths (24) of Figure 2 are positioned between elastic legs (24). Another possible application would be to have the conductive paths (24) positioned externally to the leg elastics, which may offer detection that the liquid discharge not only left the absorbent core (2), but also went beyond the leg elastics and , therefore out of article (1) (and probably dripped down to the user's legs).
[00107] The control unit described above has a memory card for recording data, it is possible, however, that the control unit can be supplied with a wireless transmitter so that data recording can be done remotely , such as on a memory disk in a central computer, for example, in a nursing home. This could save battery power when the wireless transmitter uses less power than is needed to write data to physical memory, as envisaged as part of the control unit. In another variation, the wireless transmitter and the memory card can be supplied as part of the control unit to provide data recording redundancy to prevent loss of information.
[00108] In the above description of the impedance measurement circuit, the impedance measurement circuit is configured to start measurements at regular intervals, once the control unit has been placed in electrical contact with the contacts (14) of the article absorbent (1). One possibility would be to record the data at extended intervals until a first liquid discharge event is indicated by the impedance measurement circuit and, subsequently, to record the data more frequently. This allows the memory and battery to be saved while simultaneously ensuring
Petition 870190119101, of 11/18/2019, p. 45/95
35/35 enough data when needed.
Core integrity test - hardy
Purpose and field of application
[00109] This method is designed to measure how many times an absorbent product can be lifted up to 40 mm and fall, before the product core breaks.
Principle
[00110] The absorbent product is subjected to repeated physical effort, rising and falling until the core breaks. The number of falls before the rupture of the core is used to assess the strength of the core.
Preparation
[00111] The absorbent product is stored for 24 ± 4 h at 50% ± 10% relative humidity and at 23 ° C ± 1 ° C before testing.
[00112] Cut the entire elastic band without causing damage to the core, so that the product can be hung in a flat state.
[00113] Dispense 0.9 sodium chloride solution in the product so that uniform distribution occurs. The amount of liquid is adjusted to about 1/7 of the Rothwell value for absorbent products (ISO 11948-1).
[00114] Let the product rest for 12 minutes.
[00115] Secure the product in dampers so that it hangs flat in a perpendicular position resting on a flat surface.
[00116] Loosen the product 40 mm. Repeat 100 times or until the core breaks with a drop rate of 10 drops / minute.
[00117] Note the number of falls before the rupture of the nucleus.

权利要求:
Claims (18)
[1]
1. ABSORBENT ARTICLE (1) FOR THE ABSORPTION OF
LIQUID DISCHARGES, for example, urine, menstrual or fecal fluid, when used in the crotch region of a user's body, the absorbent article (1) comprising a plurality of detection zones (4) to detect the discharge of liquid, each zone sensor (4) provided by first and second electrically conductive paths (6) that are electrically isolated from each other and arranged so that a liquid discharge between the first and second conductive paths (6) allows electrical current to flow between the first and second conductive paths (6), which is capable of being detected to detect the presence of liquid discharge in the respective zone (4), in which the plurality of zones (4) is distributed longitudinally in relation to the absorbent article ( 1) along an absorbent core (2) of the absorbent article (1) to allow the longitudinal extent of the discharge to be determined, where each of the first and second conductive paths (6) is connected to cont acts to electrically contact the first and second conductive paths (6) to a control unit (12) by means of a respective connection (16);
characterized by the connections (16) being isolated from the absorbent core (2) of the absorbent article (1), in which the first and second conductive paths (6) are in electrical contact with the absorbent core (2);
the first and second conductive paths (6) being elongated and transversely aligned, where the connections (16) extend from a contact area of the control unit (12) of the absorbent article (1) to the respective path electrically conductive (6);
wherein the respective connections (16) are arranged on one side of an electrically insulating layer of the absorbent article (1) and the first and second conductive paths (6) are arranged on the other side of the layer
Petition 870190119101, of 11/18/2019, p. 47/95
[2]
2/5 insulator to be in electrical contact with the absorbent core (2);
where the electrically conductive paths (6) and the connections (16) are a unitary conductive path in transition from the conductive path (6) to the respective connection (16) at a point (20) at which the unitary conductive path extends through the electrically insulating layer.
2. ABSORBENT ARTICLE (1), according to claim 1, characterized in that it comprises a top sheet to allow the discharge of liquid to enter the absorbent article (1) and a back sheet to prevent the discharge of liquid from escaping from the article absorbent (1) and the absorbent core (2) captured between the top and back sheets, where the detection zones (4) are distributed over at least 30% of the longitudinal extent of the absorbent core (2), preferably at least 40%, preferably at least 50%, preferably at least 60%, preferably at least 70% or, preferably at least 80%.
[3]
3. ABSORBENT ARTICLE (1), according to any one of claims 1 to 2, characterized in that there are at least three, four, five, six, seven, eight, nine, ten, eleven, twelve, fifteen, twenty, thirty or even fifty detection zones (4).
[4]
4. ABSORBENT ARTICLE (1) according to any one of claims 1 to 3, characterized in that it comprises the backsheet to prevent the discharge of liquid from escaping from the back of the absorbent article (1) and the top sheet to allow that the discharge of liquid enters the absorbent article (1), which together capture the absorbent core (2), the first and the second conductive paths (6) extending laterally at least about 50% of the lateral measurement of the absorbent core (2) in their respective location, preferably at least about 60%, preferably at least about 70%, preferably at least about 80% and preferably at least about 90%.
Petition 870190119101, of 11/18/2019, p. 48/95
3/5
[5]
5. ABSORBENT ARTICLE (1), according to any one of claims 1 to 4, characterized in that the first and second conductive paths (6) are longitudinally spaced from each other.
[6]
6. ABSORBENT ARTICLE (1), according to any one of claims 1 to 5, characterized in that at least one of the first and second conductive paths (6) is shared between adjacent detection zones (4).
[7]
7. ABSORBENT ARTICLE (1), according to any one of claims 1 to 6, characterized in that the contacts of each of the connections (16) are arranged in the contact area of the control unit (12) of the absorbent article (1).
[8]
8. ABSORBENT ARTICLE (1), according to claim 1, characterized by the electrically insulating layer insulating the connections (16) of the absorbent core (2).
[9]
9. ABSORBENT ARTICLE (1) according to any one of claims 1 to 8, characterized in that the conductive paths (6) are oriented laterally and the connections (16) are oriented longitudinally.
[10]
10. ABSORBENT ARTICLE (1), according to any one of claims 1 to 9, characterized in that the first and second conductive paths (6) are positioned under a top surface of an absorbent core (2) of the absorbent article ( 1), and still in electrical contact with the absorbent core (2).
[11]
11. ABSORBENT ARTICLE (1), according to any one of claims 1 to 10, characterized by the conductive paths (6) being positioned under the absorbent core (2), and still in electrical contact with the absorbent core (2).
[12]
12. SYSTEM, comprising the absorbent article (1) as defined by any one of claims 1 to 11 and the
Petition 870190119101, of 11/18/2019, p. 49/95
4/5 control (12), characterized by the control unit (12) being configured to measure an electrical property between the first and the second conductive paths (6) to allow the detection of when the liquid discharge is present between the first and according to conductive paths (6) and to do so for each zone (4) of the plurality of detection zones (4).
[13]
13. SYSTEM, comprising an absorbent article (1), as defined in any of claims 1 to 11 and the control unit (12), characterized in that the absorbent article (1) is intended to absorb a user's liquid discharge when the absorbent article (1) is used in the user's crotch zone, the absorbent article (1) comprising a liquid discharge sensor comprising the plurality of detection zones (4) that detects liquid discharge based on a change in a electrical property when the absorbent article (1) is wet, where the control unit (12) is configured to subject the liquid discharge sensor to pulses of electrical energy in order to take measurements of the electrical properties with each pulse, in which the pulses are separated by a rest period that is longer than the duration of a pulse; wherein the absorbent article (1) comprises a plurality of liquid discharge sensors of this type and the control unit (12) is configured to pulse each one sequentially to determine the electrical property of each liquid discharge sensor.
[14]
14. SYSTEM, according to claim 13, characterized in that the control unit (12) comprises a battery from which the pulsed electrical energy is extracted.
[15]
15. SYSTEM, according to any one of claims 13 to 14, characterized in that the control unit (12) is mounted to the absorbent article (1).
[16]
16. SYSTEM, according to any of the claims
Petition 870190119101, of 11/18/2019, p. 50/95
5/5
13 to 15, characterized by the control unit (12) comprising a physical memory device, in which the measured electrical property is stored, preferably in association with time, where the control unit (12) comprises a buffer and the control unit (12) is configured to store a plurality of sequential electrical property measurements for a given liquid discharge sensor in the buffer, where the control unit (12) is configured to transfer the plurality of sequential property measurements electrical to physical memory, and where data storage in buffer and physical memory is powered by the battery.
[17]
17. SYSTEM, according to any one of claims 13 to 16, characterized by the pulses of electrical energy being generated after the control unit (12) has been brought into contact with a contact portion of the liquid discharge sensor.
[18]
18. SYSTEM, comprising an absorbent article (1), as defined by any one of claims 1 to 11, and the control unit (12), characterized by the first and second conductive paths (6) being longitudinally spaced from each other , and where the control unit (12) is configured to measure an electrical property between the first and the second conductive paths (6) to allow the detection of when the discharge of liquid is present between the first and the second conductive paths ( 6) and to do so for each zone of the plurality of detection zones (4).

类似技术:

---

公开号 | 公开日 | 专利标题

---

BR112013016174B1|2020-06-09|absorbent article for absorbing liquid and system discharges

---

EP2654646B1|2016-07-27|Absorbent article comprising a liquid discharge sensor

---

DK2654647T3|2015-03-02|Absorbent article with a liquid discharge sensor

---

JP6275473B2|2018-02-07|Wearing article

---

JP6339440B2|2018-06-06|Drainage sensor sheet, wearing article having drainage sensor sheet, and method for producing drainage sensor sheet

---

JP6301773B2|2018-03-28|Wearing article

---

JP6486521B2|2019-03-20|Wearing article

---

O'Donnell et al.1987|Urinary incontinence detection in elderly inpatient men

---

JP6449971B2|2019-01-09|Wearing article

---

KR102099784B1|2020-04-10|Absorbent article leak detection clothing and absorbent article leak detection method using the same

---

TWM424921U|2012-03-21|Urine amount detection and prompt device of diaper

同族专利:

---

公开号 | 公开日

---

KR20140002714A|2014-01-08|

---

CO6721056A2|2013-07-31|

---

US20130303867A1|2013-11-14|

---

CN103269668A|2013-08-28|

---

CA2820127A1|2012-06-28|

---

US9408757B2|2016-08-09|

---

EP2654648B1|2018-05-23|

---

AU2011347417B2|2016-03-10|

---

WO2012084987A2|2012-06-28|

---

MX2013007241A|2013-08-15|

---

BR112013016174A2|2018-07-10|

---

RU2594558C2|2016-08-20|

---

EP2654648A2|2013-10-30|

---

DK2654648T3|2018-07-23|

---

ES2671744T3|2018-06-08|

---

JP2014507182A|2014-03-27|

---

CA2820127C|2018-10-30|

---

MX346454B|2017-03-21|

---

AU2011347417A1|2013-07-11|

---

CN103269668B|2017-10-24|

---

KR101863281B1|2018-05-31|

---

GB201022028D0|2011-02-02|

---

JP2016195792A|2016-11-24|

---

RU2013134348A|2015-01-27|

---

MY174399A|2020-04-16|

---

WO2012084987A3|2012-09-20|

---

JP6180939B2|2017-08-16|

---

PL2654648T3|2018-11-30|

引用文献:

---

公开号 | 申请日 | 公开日 | 申请人 | 专利标题

---

---

JPH02174846A|1988-12-28|1990-07-06|Kyohei Mizushima|Leakage detection system of diaper|

---

JPH046401A|1990-04-24|1992-01-10|Shinko Electric Co Ltd|Multichannel eddy-current type non-contact displacement detecting apparatus|

---

AU690901B2|1993-05-28|1998-05-07|Fred Bergman Healthcare Pty Ltd|Improvements in or relating to the prevention reduction or management of incontinence and other distressing dangerous or potentially dangerous conditions|

---

WO1996014813A1|1993-05-28|1996-05-23|C & M Investment Nominees Pty. Ltd.|Incontinence management system|

---

US5537095A|1993-10-29|1996-07-16|Hill-Rom Company, Inc.|Incontinence detection device|

---

IL112226A|1995-01-03|1999-01-26|Shuminov Asher|Moisture-detecting liner for a diaper|

---

US5808554A|1995-01-03|1998-09-15|Shuminov; Asher|Moisture detecting liner for a diaper and a process for manufacture thereof|

---

JPH10151154A|1996-11-25|1998-06-09|Matsushita Electric Ind Co Ltd|Disposable diaper with leakage detection sensor|

---

ES2135354B1|1998-04-06|2000-05-16|Vittorio Bonacini|IMPROVEMENTS INTRODUCED IN DISPOSABLE DIAPERS.|

---

US6246330B1|1998-05-29|2001-06-12|Wyn Y. Nielsen|Elimination-absorber monitoring system|

---

US6160198A|1998-06-29|2000-12-12|The Procter & Gamble Company|Disposable article having a discontinuous responsive system|

---

JP2000022687A|1998-06-30|2000-01-21|Meidensha Corp|Wide area monitoring system|

---

JP2000325379A|1999-05-19|2000-11-28|Panetto:Kk|Diaper leakage sensor, diaper cover and diaper|

---

JP2002022687A|2000-07-04|2002-01-23|Kao Corp|Excretion detection sensor|

---

US7250547B1|2000-11-07|2007-07-31|Rf Technologies, Inc.|Wetness monitoring system|

---

AU2002303198A1|2001-03-30|2002-10-15|Augmentech, Inc.|Patient incontinence/position monitoring apparatus and method of use thereof|

---

US7221279B2|2001-06-11|2007-05-22|Nielsen Wyn Y|Elimination—absorber monitoring system|

---

EP1417662A4|2001-06-11|2008-04-16|Wyn Y Nielsen|Elimination-absorber monitoring system|

---

EP1551343A2|2002-09-23|2005-07-13|Sysmore, Inc.|System and method for assessing fluid distribution|

---

EP1356798A1|2002-04-25|2003-10-29|Chin-Chen Chen|Wetness indicator for disposable diaper|

---

JP3717068B2|2002-08-23|2005-11-16|松下電器産業株式会社|Liquid detection sensor and liquid detection device|

---

JP3666479B2|2002-09-06|2005-06-29|株式会社デンソー|Diaper change time detection device|

---

WO2004100763A2|2003-04-30|2004-11-25|Daniel Collette|Diaper wetness monitoring system|

---

JP2005032398A|2003-07-11|2005-02-03|Sony Corp|Amplifier circuit and memory device having amplifier circuit|

---

US20050156744A1|2003-09-02|2005-07-21|Pires Harold G.|Diaper wetness annunciator system|

---

US20050195085A1|2004-03-02|2005-09-08|Eugen Cretu-Petra|Wireless monitoring system of diaper wetness, motion, temperature and sound|

---

US20060061477A1|2004-09-22|2006-03-23|Ming-Hsiang Yeh|Warning and monitoring device|

---

WO2006047815A1|2004-11-03|2006-05-11|Fred Bergman Healthcare Pty. Ltd|Incontinence management system and diaper|

---

US7977529B2|2004-11-03|2011-07-12|Fred Bergman Healthcare Pty Ltd.|Incontinence management system and diaper|

---

US7394391B2|2005-04-29|2008-07-01|Kimberly-Clark Worldwide, Inc.|Connection mechanisms in absorbent articles for body fluid signaling devices|

---

JP5037043B2|2005-07-14|2012-09-26|ユニ・チャーム株式会社|Moisture detection sensor|

---

US7649125B2|2005-08-31|2010-01-19|Kimberly-Clark Worldwide, Inc.|Method of detecting the presence of an insult in an absorbent article and device for detecting the same|

---

BRPI0520789B8|2005-12-12|2021-06-22|Essity Hygiene & Health Ab|absorbent article comprising moisture detection means|

---

US8304598B2|2005-12-15|2012-11-06|Kimberly-Clark Worldwide, Inc.|Garments with easy-to-use signaling device|

---

US7855653B2|2006-04-28|2010-12-21|Medtronic, Inc.|External voiding sensor system|

---

JP2007296024A|2006-04-28|2007-11-15|Kuraray Medical Inc|Electronic diaper system|

---

NL1031745C2|2006-05-03|2007-11-06|Dansamar B V|Assembly of a diaper and a sensor.|

---

JP5027455B2|2006-06-29|2012-09-19|ユニ・チャーム株式会社|Excrement detection sensor|

---

US7733233B2|2006-10-24|2010-06-08|Kimberly-Clark Worldwide, Inc.|Methods and systems for monitoring position and movement of human beings|

---

US8299317B2|2007-03-29|2012-10-30|Kimberly-Clark Worldwide, Inc.|Absorbent articles with external access to internal conductors|

---

US20080262452A1|2007-04-18|2008-10-23|Mcginnis William J|Standalone smart disposable diaper, kit and method|

---

US8805508B2|2007-05-30|2014-08-12|Medtronic, Inc.|Collecting activity data for evaluation of patient incontinence|

---

US7760101B2|2008-06-20|2010-07-20|Kimberly-Clark Worldwide, Inc.|Method of reducing sensor corrosion in absorbent articles|

---

US8044258B2|2008-06-27|2011-10-25|Kimberly-Clark Worldwide, Inc.|Absorbent article featuring leakage warning|

---

US8628506B2|2008-06-30|2014-01-14|Kimberly-Clark Worldwide, Inc.|Multifunctional monitoring device for absorbent articles|

---

US8101813B2|2008-10-30|2012-01-24|Kimberly-Clark Worldwide, Inc.|Training progress indicator|

---

US20100241094A1|2009-03-20|2010-09-23|Sherron Mark|Smart diaper|

---

EP2496197B1|2009-11-06|2015-08-26|Fred Bergman Healthcare Pty Ltd|System for incontinence monitoring and assessment|

---

AU2011202419B2|2010-05-25|2015-01-22|Fred Bergman Healthcare Pty Ltd|A system for managing patient assessment|

---

US9224102B2|2010-06-16|2015-12-29|Fred Bergman Healthcare Pty. Ltd.|Apparatus and method for analysing events from sensor data by optimisation|US10271998B2|2011-06-03|2019-04-30|The Procter & Gamble Company|Sensor systems comprising anti-choking features|

---

CN104011769A|2011-12-21|2014-08-27|Sca卫生用品公司|Method For Measuring The Absorption Of Fluid In An Absorbent Product|

---

CN108283542B|2011-12-21|2021-06-01|易希提卫生与保健公司|Method and mobile device for monitoring the use of an absorbent product|

---

CN107045590B|2011-12-21|2020-05-29|易希提卫生与保健公司|Method and apparatus for monitoring use of absorbent products|

---

CN104519846B|2012-06-15|2018-03-09|It健康有限公司|It make use of the stool and urine detection sensor and detection means of conducting fibre shape wire|

---

WO2015021243A1|2013-08-08|2015-02-12|The Procter & Gamble Company|Sensor systems for absorbent articles comprising sensor gates|

---

JP6322414B2|2014-01-06|2018-05-09|ユニ・チャーム株式会社|Absorbent article replacement timing determination device and absorbent article replacement timing determination method|

---

KR102302957B1|2014-10-31|2021-09-17|킴벌리-클라크 월드와이드, 인크.|Disposable product quantification and management|

---

US10028701B2|2014-11-03|2018-07-24|Attends Healthcare Products, Inc.|Disposable insert having sensor and RFID|

---

JP6401642B2|2014-12-25|2018-10-10|花王株式会社|Residual urine volume measurement support system|

---

US10117790B2|2015-02-26|2018-11-06|Johnson & Johnson Vision Care, Inc.|Personal hygiene product with a digital element|

---

CA2976512A1|2015-02-27|2016-09-01|Kimberly-Clark Worldwide, Inc.|Absorbent article leakage assessment system|

---

CN104720829A|2015-03-19|2015-06-24|御基集团有限公司|Method and device for obtaining feedback information of absorbent product|

---

CN104758123A|2015-04-28|2015-07-08|彭艳燕|Intelligent sanitary towel and panty liner|

---

US10624804B2|2015-08-18|2020-04-21|Hill-Rom Services, Inc.|Microclimate management airflow control based on incontinence detection|

---

US10307303B2|2015-12-22|2019-06-04|Sca Hygiene Products Ab|Wearable absorbent article|

---

JP2016047480A|2016-01-13|2016-04-07|花王株式会社|Urination detecting device|

---

US10285871B2|2016-03-03|2019-05-14|The Procter & Gamble Company|Absorbent article with sensor|

---

NO341931B1|2016-06-17|2018-02-26|Sensor Communication As|Diaper sensor device, method and system for diaper surveillance|

---

KR200488151Y1|2017-01-11|2019-03-11|김지민|Smart menstruation sensing device using moisture sensor|

---

WO2018172349A1|2017-03-21|2018-09-27|Roche Diabetes Care Gmbh|Medical device and method for manufacturing a medical device|

---

KR102099784B1|2017-04-05|2020-04-10|킴벌리-클라크 월드와이드, 인크.|Absorbent article leak detection clothing and absorbent article leak detection method using the same|

---

IT201700040831A1|2017-04-12|2018-10-12|Roberto Raggi|SYSTEM FOR THE CONTROL OF ABSORBENT ITEMS FOR HYGIENE.|

---

US10492959B2|2017-05-07|2019-12-03|Dongguan Southstar Electronics Limited|Method for indicating and alarming about wet level of diaper|

---

CN107255654B|2017-05-26|2021-04-13|李涛|Method and device for detecting liquid of paper diaper|

---

JP6560790B2|2017-05-30|2019-08-14|花王株式会社|Device for suggesting how to apply absorbent articles|

---

WO2019060910A2|2017-09-25|2019-03-28|Doshi Siddhant Anish|Sheet replacement system|

---

JP2019062991A|2017-09-28|2019-04-25|大和ハウス工業株式会社|Excrement detection device|

---

AU2018389136A1|2017-12-21|2020-05-28|Johnson & Johnson Consumer Inc.|Personal hygiene product with a digital element|

---

US10849781B2|2017-12-22|2020-12-01|Coloplast A/S|Base plate for an ostomy appliance|

---

US11051996B2|2018-08-27|2021-07-06|The Procter & Gamble Company|Sensor devices and systems for monitoring the basic needs of an infant|

---

EP3787583A1|2018-05-04|2021-03-10|The Procter & Gamble Company|Sensor devices and systems for monitoring the basic needs of an infant|

---

US11156575B2|2018-12-11|2021-10-26|Brady Worldwide, Inc.|Sorbent with detection array|

---

BR112021011142A2|2018-12-20|2021-08-31|Essity Hygiene And Health Aktiebolag|SYSTEM, KIT, HYGIENE MONITORING DEVICE AND HYGIENE MONITORING METHOD|

---

CN109700603A|2019-01-31|2019-05-03|哈尔滨医科大学|A kind of smart membranes pressure sensing diaper|

---

EP3906905A1|2020-05-07|2021-11-10|Ontex BV|Absorbent articles having integrated exudate monitoring|

---

WO2022002362A1|2020-06-30|2022-01-06|Essity Hygiene And Health Aktiebolag|Method of assessing a degree of saturation of an absorbent hygiene article|

法律状态:
2018-12-18| B06F| Objections, documents and/or translations needed after an examination request according [chapter 6.6 patent gazette]|

---

2019-01-22| B25D| Requested change of name of applicant approved|Owner name: ESSITY HYGIENE AND HEALTH AKTIEBOLAG (SE) |

---

2019-08-20| B06U| Preliminary requirement: requests with searches performed by other patent offices: procedure suspended [chapter 6.21 patent gazette]|

---

2020-04-22| B09A| Decision: intention to grant [chapter 9.1 patent gazette]|

---

2020-06-09| B16A| Patent or certificate of addition of invention granted [chapter 16.1 patent gazette]|Free format text: PRAZO DE VALIDADE: 20 (VINTE) ANOS CONTADOS A PARTIR DE 20/12/2011, OBSERVADAS AS CONDICOES LEGAIS. |

优先权:

---

申请号 | 申请日 | 专利标题

---

GBGB1022028.3A|GB201022028D0|2010-12-23|2010-12-23|Tool for analysing liquid discharge data in an absorbent article, an absorbent article adapted for liquid dicharge data collection and a control unit|

---

GB1022028.3|2010-12-23|

---

PCT/EP2011/073456|WO2012084987A2|2010-12-23|2011-12-20|Tool for analysing liquid discharge data in an absorbent article, an absorbent article adapted for liquid discharge data collection and a control unit interacting with the absorbent article for collecting the liquid discharge data|

---