JP6401601B2 - Urination dynamics analyzer - Google Patents

Description

  The present invention relates to a micturition dynamics analysis device, and more particularly to a micturition kinetics analysis device and a micturition kinetics analysis for processing urination data of a wearer detected by a plurality of sensor elements attached to an absorbent article to analyze the urination dynamics. Regarding the method.

  In recent years, as an aging society progresses, in a hospital, a nursing facility, etc., for example, nursing a bedridden person is increasing. For example, to care for a bedridden caregiver, it is necessary to appropriately manage urination. In particular, if the cared person cannot urinate by himself and is forced to wear an absorbent article such as a diaper, the presence or absence of urination by the cared person, the time of replacement of the diaper, etc. It is necessary to manage appropriately.

  As a method of managing urination of a care recipient who wears an absorbent article such as a diaper in a hospital or a nursing facility, a caregiver such as a nurse is generally used about 6 to 8 times a day, for example. A method was adopted, such as patrolling at a predetermined time, confirming the presence or absence of urination by the cared person, and appropriately replacing diapers etc. as necessary. Since urination has not yet been performed, it is not an efficient management method, and when the number of care recipients increases, the burden on the caregiver increases. For the cared person, for example, when urination is performed immediately after the patrol by the carer, if the diaper or the like is not exchanged until the next patrol, the cared person is uncomfortable and unsanitary.

  From such things, a plurality of sensor elements are attached to an absorbent article such as a diaper worn by a wearer such as a care recipient, and by these sensor elements, the presence or absence of urination by the wearer is detected, Urination detection that allows the caregiver to be notified via urinal call, etc. when urination occurs, and measures the amount of urine absorbed and urine from the spread of urine absorbed by the absorbent article during urination Devices and excretion detection devices have been developed (see, for example, Patent Documents 1 and 2).

JP 2013-39158 A JP 2011-78791 A

  In the urination detection device of Patent Document 1, a capacitive sensor sheet in which a plurality of electrodes serving as sensor elements are attached to an absorbent article, and urine is absorbed into the absorbent article by the plurality of sensor elements. By detecting the change in impedance between the electrodes due to this, the presence or absence of urination can be detected. In addition, the amount of urine absorbed and the amount of urination can be measured from the spread of urine absorbed in the absorbent article detected by a plurality of sensor elements, using a predetermined formula. .

In Patent Document 1, there is a high correlation between the output change amount by the capacitance sensor and the urine spreading area in the absorbent article, the output change amount by the capacitance sensor, and the absorption. It is described that there is also a high correlation with the amount of urine absorbed by the property article. Further, the output interval of data detected by the sensor element is preferably 0.1 seconds to 3 minutes, more preferably less than 3 seconds, and the way in which urine spreads can be grasped as the urination rate. It is also described that the urine flow rate ( urine flow rate ) per second can be calculated using the measured value of the urination rate.

  Further, in Cited Document 2, the excretion detection device includes an excretion sensor that detects a total amount of impedance change of sensor elements arranged over a wide range in the absorbent article, an attitude sensor that detects the attitude of the care recipient, and this attitude. A posture determination unit that determines the posture of the care receiver based on the posture sensor output from the sensor, and a plurality of relationships indicating the relationship between the output of the excretion sensor and the urine volume based on the posture of the care receiver obtained by the posture determination unit. It is described that a calibration curve of a corresponding posture is selected from the calibration curve, and a urine volume calculation unit that calculates the urine volume based on the calibration curve of the selected posture is described.

However, in the urination detection device of Patent Document 1 and the excretion detection device of Cited Document 2, there is a high correlation between the output change amount by the capacitance sensor and the urine spreading area in the absorbent article, There is a high correlation between the area of urine spreading and the amount of urine absorbed, the ability to calculate the amount of urine per second (urine flow rate), and the care recipient based on the posture sensor output from the posture sensor. It is described that the urine volume can be calculated with high accuracy by determining the posture of the human body, but since the verification results by these devices have been made at the so-called laboratory level, these devices are When actually used in a nursing facility or the like, various problems peculiar to these devices are expected to occur.

  For example, in a hospital or a nursing facility, when a wearer such as a care receiver wears an absorbent article to which a plurality of sensor elements are attached, what is absorbed by the absorbent article is not limited to the urination of the wearer. Since it may be other body fluids such as sweat, it is necessary to remove as much as possible the influence of other than urination in order to accurately measure the amount of absorption and urination.

  The present invention is able to remove influences other than urination from data detected by a plurality of sensor elements attached to an absorbent article, such as average urine flow rate, maximum urine flow rate, urine flow rate curve, etc. An object of the present invention is to provide a micturition dynamic analysis apparatus and a micturition dynamic analysis method capable of analyzing the micturition kinetics of the urine with high accuracy.

  In the present invention, a plurality of sensor elements attached to an absorbent article detect a change in impedance such as capacitance when urine is absorbed by the absorbent article, and process the detected change in impedance over time. A urination dynamic analysis device including a urination analysis unit for analyzing urination dynamics, the urination analysis unit comprising: an absorption amount calculation unit, a urination extraction unit, a urination selection unit, a urination dynamic analysis unit, The absorption amount calculation unit is configured to detect urine absorption at the time of each detection from the spread of urine absorbed by the absorbent article, which is continuously detected by the plurality of sensor elements over time. The urine extraction unit removes noise from each detected urine absorption amount data calculated by the absorption amount calculation unit, and the absorbent article during urination is calculated. Change of urine absorption by aging The urination selection unit is configured to extract data after the exchange of the absorbent article for the chronological change in the amount of urine absorbed at the time of urination extracted by the urination extraction unit. It is determined whether the urine absorption amount of the urine is absorbed over time, and the data of the urine absorption amount over time of each urination is selected. Achieving the above objective by providing a micturition dynamics analysis device that analyzes the urinary kinetics of each urination from the data of changes in urine absorption during each urination selected by the selection unit It is.

  Further, the present invention processes the urination data of the wearer based on the change over time of the impedance when the absorbent article absorbs urine, which is detected by a plurality of sensor elements attached to the absorbent article, A urination dynamic analysis method for analyzing urination dynamics, comprising at least an absorption amount calculation step, a urination extraction step, a urination selection step, and a urination dynamic analysis step, wherein the absorption amount calculation step includes the plurality of sensors. The amount of urine absorbed at each detection is calculated from a spread of urine absorbed by the absorbent article continuously detected by the element using a predetermined calculation formula, and the urination In the extraction step, noise is removed from the urine absorption amount data at the time of detection calculated in the absorption amount calculation step, and urine absorption by the absorbent article during urination is performed. In the urination selection step, the number of times after the absorbent article is replaced with respect to the chronological change in the amount of urine absorbed at the time of urination extracted in the urination extraction step Data of the urine absorption amount at the time of urination is determined, and the data of the chronological change of the urine absorption amount at the time of each urination is selected, and the urination dynamic analysis step is selected by the urination selection step. The above object is achieved by providing a method of analyzing urination dynamics for analyzing the urination dynamics at the time of each urination from the data of the chronological change of the urine absorption amount at the time of each urination.

  According to the micturition kinetic analysis apparatus or the micturition kinetic analysis method of the present invention, it is possible to remove influences other than urination from data detected by a plurality of sensor elements attached to the absorbent article, and to reduce the mean urine flow The urination dynamics such as the rate, maximum urinary flow rate, and urinary flow rate curve can be analyzed with high accuracy.

It is a figure explaining the structure of the urination management system in which the urination dynamic analysis apparatus which concerns on preferable one Embodiment of this invention was integrated. It is a figure explaining the structure of the urination dynamic analysis apparatus which concerns on preferable one Embodiment of this invention. (A) is a figure explaining the structure of the diaper which is an absorbent article, (b) is a figure explaining the structure of a urine picking pad, (c) is a figure explaining the structure of an electrostatic capacitance sensor sheet | seat. It is a figure explaining the structure of a data collection means. It is a flowchart explaining an absorption amount calculation part and a urination extraction part. (A), (b) is a chart explaining a differential waveform determination part. It is a flowchart explaining a urination selection part. It is a flowchart explaining a notification determination part. It is a flowchart explaining a urination dynamics analysis part. (A), (b) is a chart which illustrates the analysis result of the urine flow rate analyzed by the micturition dynamics analysis part.

  The urination dynamic analysis apparatus 10 (see FIGS. 1 and 2) according to a preferred embodiment of the present invention manages the urination of bedridden caregivers at the same time, for example, in a hospital or a nursing facility, and so on. It is incorporated into a urination management support system 50 for reducing the burden on the caregiver. The urination dynamic analysis device 10 of the present embodiment is formed in the information processing means 20 comprising a urination management support system 50, for example, a computer, and from the absorbent article 30 such as a diaper via the data collection means 40. The data relating to urination detected by the sensor element 31 (see FIG. 3) is processed, and the urination dynamics of the cared person (wearer), for example, the average urinary flow rate, maximum urinary flow rate, urine during urination It has a function that enables analysis of flow rate curves and the like with high accuracy.

  As shown in FIGS. 1 and 2, the urination dynamic analysis device 10 of the present embodiment is formed by an information processing means 20 including, for example, a computer, and a plurality of sensor elements 31 (see FIG. 3) attached to an absorbent article 30. ) Includes a urination analysis unit 11 for detecting a change in impedance when urine is absorbed by the absorbent article 30, processing the detected change in impedance over time, and analyzing urination dynamics. . As shown in FIG. 2, the urination analysis unit 11 includes an absorption amount calculation unit 12, a urination extraction unit 13, a urination selection unit 14, and a urination dynamic analysis unit 15. The absorption amount calculation unit 12 is preferably a predetermined calculation that is preferably determined in advance from the impedance value that reflects the spread of urine absorbed by the absorbent article 30 continuously detected by the plurality of sensor elements 31 over time. Using the formula, the amount of urine absorbed at each detection is calculated. The urine extraction unit 13 removes noise from the urine absorption amount data at the time of detection calculated by the absorption amount calculation unit 12, and data of changes in the urine absorption amount by the absorbent article 30 during urination over time. To extract. The urine selection unit 14 changes the time-dependent change in the urine absorption amount at the time of urination after exchanging the absorbent article 30 for the data of the time-dependent change in the urine absorption amount at the time of urination extracted by the urine extraction unit 13. The data of the urine absorption amount at the time of each urination is selected. The micturition dynamics analysis unit 15 analyzes the micturition kinetics at each urination from the data of the chronological change of the urine absorption amount at each urination selected by the urination selection unit 14.

  Moreover, in this embodiment, the urination analysis part 11 is provided with the attitude | position determination part 16 which determines a wearer's attitude | position, and the absorption-quantity calculation part 12 is the attitude | position determination means 16 from several predetermined formula. The predetermined calculation formula corresponding to the posture of the wearer determined by the above is selected, and the urine absorption amount at the time of each detection by the plurality of sensor elements 31 is calculated.

  Furthermore, in this embodiment, the urination analysis unit 11 includes a notification determination unit 17. The notification determination unit 17 monitors the calculation result of the urine absorption amount by the absorption amount calculation unit 12, determines that the urine absorption amount absorbed by the absorbent article 30 exceeds a predetermined set value, and the urine absorption amount Is notified that it is time to measure the amount of residual urine after urination.

  In the present embodiment, the urination management support system 50 in which the urination dynamic analysis device 10 is incorporated, as shown in FIG. 1, absorbs a plurality of sensor elements 31 that detect the spread of urine based on a change in impedance. And a data collection means 40 that houses a power supply for supplying a current to the sensor element 31 (see FIGS. 3A to 3C) and collects a change in impedance detected by the sensor element 31 as data. The information processing means 20 constituting the urination dynamic analysis device 10 and the notification means 25 for notifying the caregiver such as a nurse of the notification from the information processing means 20 are provided.

  As shown in FIG. 1 and FIGS. 3A to 3C, the absorbent article 30 constituting the urination management support system 50 has the same configuration as the urine collection pad described in JP2013-39158A. The urine absorbing pad 33 is a disposable diaper mounted as an absorbent part of the absorbent article 30. The urine removing pad 33 is formed by, for example, forming a sensor element 31 with a plurality of electrodes on one surface of a vertically long film base on the outer surface opposite to the side that touches the wearer's skin. A capacitance sensor sheet 32 is attached. The plurality of sensor elements 31 are arranged in two rows in the longitudinal direction of the capacitance sensor sheet 32. A plurality of sensors capable of detecting the spread of urine based on a change in impedance in the absorbent article 30 by attaching the urine removing pad 33 to the diaper which is the absorbent article 30 as an absorbent portion. The element 31 will be attached. Each of the plurality of electrodes constituting the sensor element 31 is connected by a conducting wire, and is connected to the data collection means 40 attached to the absorbent article 30 via the connector portion 34 (see FIG. 1). The urine removing pad 33 of the absorbent article 30 absorbs, for example, a urinary amount of 350 g or more as a urinary amount several times the normal urination amount of about 150 g for a normal adult. Therefore, the amount of the polymer contained in the urine collection pad 33 is adjusted.

  The data collection means 40 has a power source for applying a voltage to the sensor element 31 and has a function of collecting a change in impedance detected by the sensor element 31 as urination data. Specifically, as shown in FIG. 4, the data collection means 40 in this embodiment includes a housing 41 that houses a battery (not shown) that is a power source and a timer 45. The housing 41 is detachably fixed to the ventral region of the absorbent article 30 via, for example, a metal snap 60 (see FIG. 1) provided on the absorbent article 30. The data collection means 40 can be removed from the snap 60 and reused. The data collection means 40 includes an impedance detection circuit 42, an acceleration sensor 43, a data logger 44, and the like.

  The impedance detection circuit 42 is generated by the battery and the circuit in the housing 31 over the entire circuit formed by the plurality of sensor elements 31 of the capacitance sensor sheet 32 attached to the urine collection pad 33 of the absorbent article 30, for example, 400 kHz. A change in impedance between the plurality of sensor elements 31 is detected by applying a rectangular wave voltage of about 700 kHz. The impedance detection circuit 42 stores the change in impedance of the capacitance sensor sheet 32 in the data logger 44 together with the time data output from the timer 45. Here, the time interval of the change in impedance detected by the sensor element 31, that is, the measurement interval of urination data can be appropriately adjusted, for example, between 0.1 second and 3 minutes. The measurement interval of urination data is preferably 0.1 second to 3 minutes, more preferably 0.1 to 60 seconds, and particularly preferably 0.2 to 20 seconds.

  The acceleration sensor 43 detects (collects) accelerations in the X direction, the Y direction, and the Z direction due to the displacement of the posture of the wearer wearing the absorbent article 30, together with time data output from the timer 45, The detection result is stored in the data logger 44.

  The data logger 44 stores data acquired from the impedance detection circuit 42 and the acceleration sensor 43. The data logger 44 transfers the stored data to the information processing means 20 in response to a request from the information processing means 20 or when it is detected that the data logger 44 is connected to the information processing means 20.

  The information processing means 20 constituting the urination management support system 50 is known as, for example, a computer, and includes a central processing unit (CPU), a read only memory (ROM), a random access memory (RAM), a hard disk drive (HDD). ), Display means 21, input means 22, output means 23, and the like. As shown in FIG. 2, the information processing unit 20 includes a urination dynamic analysis device 10 to be described later including a urination analysis unit 11 for analyzing urination dynamics by incorporating a predetermined program. . The urination dynamic analysis apparatus 10 acquires urine data from the data collection means 40 in addition to the urination analysis unit 11 including an absorption amount calculation unit 12, a urination extraction unit 13, a urination selection unit 14, a urination dynamic analysis unit 15 and the like which will be described later. A data acquisition unit 19 is provided. Further, the urination dynamic analysis apparatus 10 includes the urination data sent from the data collection means 40 acquired via the data acquisition unit 19, the absorption amount calculation unit 12, the urination extraction unit 13, the urination selection unit 14, and the urination dynamic analysis unit. A database unit 24 for accumulating various data calculated and analyzed at 15 etc. is provided. The database unit 24 can also accumulate, for example, data related to a urination diary describing the wearer's water consumption, defecation, bathing, and the like, which is taken in via the input means 22, for example.

  The display means 21 is configured by an LCD (Liquid Crystal Display), an EL display (Electroluminescence display), or the like. The input means 22 is configured by, for example, a touch panel or a keyboard. The output unit 23 is connected to the notification unit 25 via, for example, a wired cable or a wireless LAN system.

  The notification unit 25 notifies the terminal device 26 of information from the information processing unit 20 using a network that a hospital, a nursing care facility, or the like has as an infrastructure. For example, the notification unit 25 is configured using a hospital call system in a hospital. can do. The notification means 25 includes a switch 27 installed for each patient room of a wearer (caregiver) who wears the absorbent article 30 and a repeater 28 connected to each switch 27. The repeater 28 collects information of the plurality of switches 27. The notification means 25 includes a hospital exchanger 29 connected to the repeater 28 and a terminal device 26 carried by a caregiver such as a nurse connected to the hospital exchanger 29. Thus, for example, when the notification determination unit 17 of the urination analysis unit 11 of the urination dynamic analysis device 10 to be described later determines that the amount of urine absorbed absorbed by the absorbent article 30 has exceeded a predetermined set value, the notification unit Through 25, the determination result is promptly notified to a caregiver such as a nurse, so that the timing for measuring the amount of residual urine after urination and the timing for replacing the diaper, which is the absorbent article 30, can be notified efficiently. Be able to.

  As shown in FIG. 2, the urination dynamic analysis device 10 of this embodiment includes a urination analysis unit 11 including an absorption amount calculation unit 12, a urination extraction unit 13, a urine selection unit 14, a urination dynamic analysis unit 15, and the like. In addition, a data acquisition unit 19 that acquires urination data from a data collection unit 40 attached to the absorbent article 30 and a database unit 24 that stores various data are provided.

  The absorption amount calculation unit 12 detects a change in impedance detected by the plurality of sensor elements 31 attached to the absorbent article 30 when urine is absorbed in the absorbent article 30, and detects the detected impedance change. The absorption amount calculating step of the micturition dynamics analysis method that analyzes the micturition kinetics by processing over time is performed. In the urination extraction unit 13, a urination extraction step of the urination dynamic analysis method is performed. In the urination selection unit 14, a urination selection step of the urination dynamic analysis method is performed. The urination dynamic analysis unit 15 performs a urination dynamic analysis step of the urination dynamic analysis method.

  In the present embodiment, the data acquisition unit 19 is connected to the data collection means 40 attached to the absorbent article 30 via a wired cable or a wireless LAN system. The data acquisition unit 19 acquires the urination data stored in the data logger 44 of the data collection unit 40 and accumulates it in the database unit 24, and the acquired urination data is used for the urination analysis unit 11 of the urination dynamic analysis device 10. , The function is provided as data for calculating the amount of urine absorption and analyzing the urination dynamics during urination.

  In the absorption amount calculation unit 12, as the absorption amount calculation step, the data acquisition unit 19 sequentially detects the plurality of sensor elements 31 of the capacitance sensor sheet 32 attached to the absorbent article 30 over time. From the urination data (impedance or data on the amount of change thereof) relating to the spread of urine absorbed by the absorbent article 30, urine absorption at each detection is preferably performed using a predetermined calculation formula. Calculate the amount (see Figure 5). That is, the absorption amount calculation unit 12 has absorbed in accordance with the urine spreading area related to various absorbent articles 30 of the pad types with different standards that have been verified in advance in a laboratory or the like and accumulated in the database unit 24. A correlation equation corresponding to the pad type of the absorbent article 30 worn by the wearer is selected from a plurality of correlation equations expressing the urine absorption amount, which is the amount of urine, by the amount of change in impedance. Here, the correlation formula may be the same calculation formula over the entire impedance range or a different calculation formula depending on the impedance range, but in order to improve the accuracy of the urine absorption amount as a calculation result It is preferable to use different calculation formulas depending on the impedance range. Moreover, it is preferable that each calculation formula is a polynomial, and it is preferable that the order is 1st to 4th. The amount of urine absorbed at the time of detection is calculated for each predetermined measurement time interval from the amount of change in impedance detected by the plurality of sensor elements 31. The absorption amount calculation unit includes a data smoothing unit that performs a data smoothing step of the absorption amount calculation step. When calculating the amount of urine absorbed, the impedance that changes over time is smoothed in advance by, for example, a peak hold, a low-pass filter, a moving average, etc. by a data smoothing step in the data smoothing unit, and then the amount of urine absorbed at the time of detection is calculated. Each may be calculated.

  Moreover, in this embodiment, the urination analysis part 11 is a wearer's attitude | position from the data regarding the attitude | position detected by the acceleration sensor 43 transferred from the data collection means 40 with the urination data acquired by the data acquisition part 19. Is provided. In the posture determination unit 16, the posture determination step of the above-described urination dynamic analysis method is performed. The posture determination unit 16 uses, as a posture determination step, from the data regarding the posture by the acceleration sensor 43, for example, the wearer is in a sitting state, a supine state, a knee bending state, a lateral state thereof, a prone state, etc. It is determined in which state. The absorption amount calculation unit 12 corresponds to the posture of the wearer determined by the posture determination means 16 from a plurality of calculation formulas that are stored in the database unit 24 and verified in advance for each posture in the absorption amount calculation step. A predetermined calculation formula is selected, and the amount of urine absorbed at the time of detection by the plurality of sensor elements 31 is calculated (see FIG. 5). This makes it possible to calculate the urine absorption amount at the time of detection with higher accuracy.

  In the urine extraction unit 13, as the urine extraction step, noise is removed from the urine absorption amount data at the time of detection by each of the plurality of sensor elements 31 calculated by the absorption amount calculation unit 12, and the absorbency at the time of urination is determined. Data of changes over time in the amount of urine absorbed by the article 30 is extracted. That is, in the urine extraction unit 13, as shown in FIG. 5, for example, a calculated value of the calculated urine absorption amount with respect to the data of the urine absorption amount detected over time at each predetermined measurement interval. When is less than or equal to 0, this data is determined to be noise that is not urination data and is cut. In addition, when the difference between the calculated value of the urine absorption at the time of the current detection and the calculated value of the urine absorption at the time of the previous detection is, for example, 5 g or less, the current data is It is judged that the noise is not the data of and is cut. Furthermore, if the calculated value of urine absorption at the time of the next detection is less than the calculated value of urine absorption at the time of the current detection, the current data is judged to be noise that is not data during urination and cut. To do.

  In the present embodiment, the urination analysis unit 11 includes a differential waveform determination unit 18 (see FIG. 5). In the differential waveform determination unit 18, the differential waveform determination step of the above-described urination dynamic analysis method is performed. As a differential waveform determination step in the urine extraction step, the differential waveform determination unit 18 uses a differential waveform from data of changes in urine absorption over time at each detection by the plurality of sensor elements 31 calculated by the absorption amount calculation unit 12. Urine extraction unit 13 determines and removes noise based on the obtained differential waveform. That is, the differential waveform determination unit 18 performs a differential operation on the data of changes in urine absorption over time based on the urination data calculated by the absorption amount calculation unit 12 and detected at predetermined measurement intervals. Thereby, for example, as shown in FIGS. 6A and 6B, it is possible to obtain a graph of the differential waveform, which is preferably a value obtained by moving and averaging the differential values. The differential waveform determination unit 18 determines, for example, whether or not the differential value has a large positive and negative peak from the obtained differential waveform graph. For example, as shown in FIG. 6A, the differential waveform determination unit 18 determines the amount of urine absorbed by the absorbent article 30 over time when the differential value has a large positive peak only. It can be determined that the data is change data. For example, as shown in FIG. 6B, when the differential value has positive and negative peaks continuously, it can be determined that the noise is not the data at the time of absorption and can be cut. For example, in the graph of the differential waveform obtained in FIG. 6 (a), the determination as to whether or not the urine absorption amount during urination is data over time is a peak between 30 and 60 measurement points on the horizontal axis. If the sum of the values is taken and the sum of the peak values is a positive value and exceeds, for example, 10 as a threshold value, it can also be determined that the data is a change over time in the amount of urine absorbed during urination. .

  As a result, the urination extraction unit 13 uses the urine extraction step to detect the influence of other than urination such as sweat, the influence of the absorbent polymer contained in the urine removing pad 33 of the absorbent article 30, and the influence of other factors. As a result, it is possible to extract data of changes in urine absorption over time at the time of urination with high accuracy and properly removed.

  In the urine selection unit 14, as the urine selection step, the urine at the time of urination after exchanging the absorbent article 30 with respect to the data of the temporal change of the urine absorption amount at the time of urination extracted by the urine extraction unit 13. It is determined whether or not the data is a change in absorption over time, and data on a change in absorption of urine over time at each urination is selected. That is, as shown in FIG. 7, the urination selection unit 14 calculates the estimated absorption amount based on the data of changes in the urine absorption amount with time at the time of each urination extracted by the urination extraction unit 13. The estimated absorption amount is preferably calculated by selecting the urine absorption amount after the time until the absorbent polymer contained in the urine absorption pad 33 absorbs urine and stabilizes (until the spread ends), for example, from 3 minutes It is preferable to use the calculated amount of absorption after 5 minutes. Furthermore, if the average value at 10 points from the measurement points after 3 to 5 minutes is taken, it is possible to estimate the urine absorption amount with higher accuracy. Here, the calculated value of the estimated absorption amount can be a value calculated by a predetermined calculation formula corresponding to the posture of the wearer. Further, “after 3 minutes” is the time after 3 minutes from the time when urination is detected by the urine extraction unit 13, and the estimated absorption amount is preferably rounded off, for example, to an average value of 1 for convenience of calculation. .

  When the estimated absorption amount is calculated for the chronological change in urine absorption during each urination, the time-dependent change in urine absorption during each urination is calculated from the calculated estimated absorption. After changing the diaper which is 30, it is determined how many times the urine absorption is over time data of urine absorption. That is, first, for example, by collating with the time data at the time of diaper exchange stored in the database unit 24, the data on the change in urine absorption over time at the time of urination is the first after the diaper is exchanged. It is determined whether the data is during urination. This makes it possible to eliminate the influence of changing diapers. If it is determined that it is not the data at the time of the first urination after changing the diaper, determine whether the estimated absorption at the time of urination is greater than the estimated absorption at the time of urination If it is not larger than the estimated absorption at the time of urination the previous time, it is judged as noise and cut. If the estimated absorption at the time of urination is greater than the estimated absorption at the time of urination, the estimated absorption at the time of urination is subtracted from the estimated absorption at the time of urination. The estimated absorption for one time only when urinating is calculated. It is determined whether or not the calculated estimated urination amount only for the current urination only falls below, for example, 25 g as a determination value. If the determination value falls below the determination value, the urination dynamic analysis unit 15 analyzes the urination dynamics. It is not data of change over time that is effective for this, and it is judged as noise and cut. Furthermore, when the calculated estimated absorption amount only at the time of this urination is equal to or more than the judgment value, the data at this time of urination is used as the data of the urine absorption amount effective for analyzing the urination dynamics. Adopt as.

  On the other hand, if it is determined that the data is the first urination data after changing the diaper, it is determined whether or not the estimated absorption amount is greater than 0. It is judged and cut. In addition, when the estimated absorption amount at the time of the first urination is larger than 0, it is determined whether the estimated absorption amount at that time is less than, for example, 25 g as a determination value. The urination dynamic analysis unit 15 determines that the data is not data of change over time effective for analyzing the urination dynamics, and cuts the noise. When the estimated absorption amount at the time of the first urination is equal to or greater than the determination value, the data at the time of urination is employed as data of the urine absorption amount effective for analyzing the urination dynamics at the time of the first urination.

  As a result, the urination selector 14 can accurately select the data of the temporal change in the amount of urine absorption during each urination, which is effective for analyzing the urination dynamics by the urination dynamics analyzer 15.

  Moreover, in this embodiment, the urination analysis part 11 is provided with the notification determination part 17 (refer FIG. 2). The notification determination unit 17 can monitor the output of the urine selection unit 14 or the absorption amount calculation unit 12 to determine that the urine absorption amount absorbed by the absorbent article 30 has exceeded a predetermined set value. When the amount of urine absorption exceeds a predetermined set value, for example, it is notified that it is time to measure the amount of residual urine after urination. In the present embodiment, as shown in FIG. 8, the notification determination unit 17 uses, as a notification method, data on a temporal change in the amount of urine absorbed at the time of urination extracted by the urine extraction unit 13 at the time of urination. Can be selected between a method for determining whether or not a single absorption amount only exceeds a determination value and a method for determining whether or not the total amount of absorption after the current urination exceeds a determination value It is like that. That is, when the amount of absorption only at the time of urination is selected, for example, by monitoring the output of the urine selection unit 14, when it is determined that the amount of absorption only at the time of urination exceeds the determination value, Subject to external notification. When the total amount of absorption after urination is selected, for example, the output of the absorption amount calculation unit 12 is monitored, and when it is determined that the total amount of absorption after urination has exceeded the determination value, for example. , Subject to external notification. The amount of residual urine after urination is measured by notifying the terminal device 26 carried by a caregiver such as a nurse via the notification means 25 (see FIG. 1) for the information that has been notified to the outside. It is possible to efficiently notify the timing to perform, the timing to replace the diaper which is the absorbent article 30, and the like. This also makes it possible to reduce the frequency of patrol by the caregiver and reduce the burden on the caregiver. If it is determined that the amount of absorption only during the current urination does not exceed the judgment value, or if it is determined that the total amount of absorption after the current urination does not exceed the judgment value, the measurement will continue. .

  In the urination dynamic analysis unit 15 of the urination analysis unit 11, as the urination dynamic analysis step, urination during each urination is selected from the data of the urine absorption amount during each urination selected by the urine selection unit 14. Dynamics are to be analyzed. That is, in the micturition dynamic analysis unit 15, as shown in FIG. 9, from the data of the urine absorption amount at the time of each urination selected by the urination selection unit 14 over time, the data per second at each absorption time. Urine volume (urinary flow rate) is calculated, and a graph (urinary flow rate curve) of urinary flow rate (g / sec), for example, as shown in FIGS. It can be done. In the graph display of FIGS. 10A and 10B, in order to make the graph easy to see, the urinary flow rate is plotted by moving average, and preferably smoothed by 3 to 7 points moving average. In order to place the graph near the center of the figure, when the number of measurement points on the horizontal axis is 0 to 100, it is preferable to place the urination detection time at a position between 30 and 50.

  The urination dynamic analysis unit 15 measures the urination time and calculates the average urinary flow rate and the maximum urine flow rate. That is, as shown in FIG. 9, for example, in the graph display (urine flow rate curve) of the urine flow rate shown in FIGS. 10 (a) and 10 (b), the urination detection time is set at the position 40 on the horizontal axis (number of measurement points). The urination dynamics is set and displayed, and the number of data points when the value on the horizontal axis is in the range of the set value (20 to 80) and the value on the vertical axis is greater than 0 is counted. By multiplying the count number by the measurement interval, the urination time from the start of absorption to the end of absorption can be calculated. Further, the average urine flow rate can be calculated by dividing the amount of urination by the calculated urination time from the start of absorption to the end of absorption. Furthermore, for example, the maximum urinary flow rate can be calculated by detecting the maximum value of the urine flow rate measured in the range of 20 to 80 on the horizontal axis (number of measurement points) (see FIG. 10A). become. Further, for example, it is possible to analyze, for example, the urine momentum and the spread state from the graph display (urinary flow rate curve) of the urine flow rate shown in FIGS. It is also possible to analyze the influence of the water-absorbing polymer contained in 33. For example, the arrow portion in FIG. 10B indicates that the absorption of the polymer is not in time.

  Then, according to the urination dynamic analysis device 10 of the present embodiment having the above-described configuration or the urination dynamic analysis method realized by the urination dynamic analysis device 10, detection is performed by a plurality of sensor elements 31 attached to the absorbent article 30. It is possible to accurately analyze the urination dynamics such as the average urinary flow rate, the maximum urinary flow rate, and the urinary flow rate curve by removing the influence of other than urination from the obtained data.

  That is, according to the present embodiment, the urination dynamic analysis device 10 includes an absorption amount calculation unit 12, a urination extraction unit 13, a urine selection unit 14, and a urination dynamic analysis unit 15. 11, the urine extraction unit 13 removes noise from each detected urine absorption amount data calculated by the absorption amount calculation unit 12 and absorbs urine by the absorbent article 30 during urination. The urinary selection unit 14 replaces the absorbent article 30 with respect to the chronological change in the amount of urine absorbed at the time of urination extracted by the urination extraction unit 13. After that, it is determined how many times the urine absorption amount is changed over time, and data of the urine absorption amount over time during each urination is selected.

  Therefore, according to the urination dynamic analysis device 10 of the present embodiment or the urination dynamic analysis method realized by the urination dynamic analysis device 10, the impedance over time detected by the plurality of sensor elements attached to the absorbent article. From the urination data based on various changes, it is possible to effectively remove the influence of other body fluids such as sweat other than urination and the influence of other factors such as diaper exchange, and the absorbent article 30 at the time of individual urination Since the data of changes in urine absorption due to aging can be extracted with high accuracy, the average urinary flow rate, maximum urine flow rate, It becomes possible to analyze urination dynamics such as a rate curve with high accuracy.

  The present invention is not limited to the above-described embodiment, and various modifications can be made. For example, the urination dynamic analysis device 10 of the present invention does not necessarily need to be incorporated and used in a urine management support system that collectively manages urination of a care recipient in, for example, a hospital or a care facility. The determination unit, the notification determination unit, or the differential waveform determination unit may not be provided.

DESCRIPTION OF SYMBOLS 10 Urination dynamic analysis apparatus 11 Urination analysis part 12 Absorption amount calculation part 13 Urination extraction part 14 Urination selection part 15 Urination dynamics analysis part 16 Posture determination part 17 Notification determination part 18 Differential waveform determination part 19 Data acquisition part 20 Information processing means 21 Display Means 22 Input means 23 Output means 24 Database section 25 Notifying means 26 Terminal equipment 27 Switch 28 Repeater 29 Hospital exchanger 30 Absorbent article (diaper)
31 Sensor element 32 Capacitance sensor sheet 33 Urine pad 34 Connector part 40 Data collection means 41 Housing 42 Impedance detection circuit 43 Acceleration sensor 44 Data logger 45 Timer 50 Urination management support system 60 Snap

Claims (11)

Multiple sensor elements attached to an absorbent article detect impedance changes when urine is absorbed by the absorbent article, and process the detected impedance changes over time to analyze urination dynamics A micturition dynamics analysis device including a urination analysis unit of
The urination analysis unit is configured to include an absorption amount calculation unit, a urination extraction unit, a urination selection unit, and a urination dynamic analysis unit,
The absorption amount calculation unit calculates the urine absorption amount at the time of each detection from the spread of urine absorbed by the absorbent article continuously detected by the plurality of sensor elements over time. And
The urine extraction unit removes noise from the urine absorption amount data at the time of detection calculated by the absorption amount calculation unit, and data of changes over time in the urine absorption amount by the absorbent article during urination To extract
The urination selection unit, for the data of the chronological change in the urine absorption amount at the time of urination extracted by the urine extraction unit, after replacing the absorbent article, Judgment is whether the data is change, and data of changes in urine absorption over time at each urination is selected,
The micturition dynamics analysis unit is adapted to analyze the micturition kinetics at the time of each urination from the data of change over time of the urine absorption amount at the time of each urination selected by the micturition selection unit ,
The urination analysis unit includes a differential waveform determination unit, and the differential waveform determination unit is a urine absorption at the time of each detection by the plurality of sensor elements calculated by the absorption amount calculation unit in the urine extraction unit. A micturition dynamics analysis device that obtains a differential waveform from quantity data and determines and removes noise from the obtained differential waveform .   The micturition dynamics analysis unit is selected by the micturition selection unit, from the data of changes in urine absorption over time at each urination, as urination dynamics, the average urine flow rate at each urination, the maximum urine flow The urination dynamic analysis apparatus according to claim 1, wherein one or more of the rate and urine flow rate curves are analyzed.   The urination analysis unit includes a posture determination unit that determines the posture of the wearer, and the absorption amount calculation unit determines the posture of the wearer determined by the posture determination unit from a plurality of predetermined formulas. The urinary kinetic analysis apparatus according to claim 1 or 2, wherein a predetermined calculation formula corresponding to is selected, and a urine absorption amount at the time of detection by each of the plurality of sensor elements is calculated.   The urination analysis unit includes a notification determination unit, and the notification determination unit can determine that the amount of urine absorbed absorbed by the absorbent article exceeds a predetermined set value. The urination dynamic analysis device according to any one of claims 1 to 3, wherein when the absorption amount exceeds a predetermined set value, it is notified that it is time to measure the amount of residual urine after urination. . The differential waveform determination unit determines whether or not the differential value has positive and negative peaks continuously from the obtained differential waveform graph, and the differential value continuously has positive and negative peaks. The urination dynamics analysis apparatus according to any one of claims 1 to 4, wherein if it has, it is determined to be noise that is not data at the time of absorption and is removed.   The absorption amount calculation unit includes a data smoothing unit, and after smoothing the time-dependent change in impedance before calculating the urine absorption amount by the data smoothing unit, calculates the urine absorption amount at each detection. The urination dynamic analysis apparatus according to any one of claims 1 to 5. Analysis to analyze urination dynamics by processing wearer's urination data based on changes in impedance over time when the absorbent article absorbs urine, detected by multiple sensor elements attached to the absorbent article A method of analyzing urination dynamics performed by a device ,
At least an absorption amount calculating step, a urination extraction step, a urination selection step, and a urination dynamic analysis step,
In the absorption amount calculating step, each detection is performed using a predetermined calculation formula determined in advance from the spread of urine absorbed by the absorbent article, which is continuously detected over time by the plurality of sensor elements. Calculate the amount of urine absorbed at the time,
In the urination extraction step, noise is removed from the data of the urine absorption amount at the time of detection calculated in the absorption amount calculation step, and data of chronological change in the urine absorption amount by the absorbent article at the time of urination Extract
In the urination selection step, the urine absorption amount at the time of urination is changed over time after exchanging the absorbent article for the data of the urine absorption amount at the time of urination extracted by the urination extraction step. Judgment whether it is change data, select the data of change over time of urine absorption at the time of each urination,
In the micturition dynamics analysis step, from the data of changes over time in the amount of urine absorbed at the time of urination selected by the micturition selection step, the micturition dynamics at the time of each urination is analyzed ,
The urination extraction step includes a differential waveform determination step, and in the differential waveform determination step, a differential waveform is obtained from urine absorption amount data at the time of detection by each of the plurality of sensor elements calculated in the absorption amount calculation step. A method for analyzing urination dynamics by determining and removing noise from the obtained differential waveform .   In the micturition dynamic analysis step, from the data of changes in urine absorption over time at each urination selected in the micturition selection step, the urination kinetics are obtained as the average urine flow rate and the maximum urine flow at each urination. The urination dynamic analysis method according to claim 7, wherein one or more of the rate and urinary flow rate curves are analyzed. A posture determination step of determining a posture of the wearer;
In the absorption amount calculating step, a predetermined calculation formula corresponding to the posture of the wearer determined by the posture determination step is selected from a plurality of predetermined calculation formulas, and each detection by the plurality of sensor elements is performed. The method for analyzing urination dynamics according to claim 7 or 8, wherein the amount of urine absorbed is calculated. The differential waveform determination step determines whether the differential value has positive and negative peaks continuously from the obtained differential waveform graph, and the differential value continuously peaks positive and negative. The method of analyzing urination dynamics according to any one of claims 7 to 9, wherein if there is, it is determined as noise that is not data at the time of absorption and is removed. The urination according to any one of claims 7 to 10, wherein the absorption amount calculating step includes a data smoothing step, and in the data smoothing step, a change with time of impedance before calculating the urine absorption amount is smoothed. Dynamic analysis method.

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