JP2015206693A - Excretion detection device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an excretion detection device capable of detecting whether or not a wearer excreted, and whether the excretion is feces or urine.SOLUTION: A sensor sheet 11 comprises at least one electrode part comprising a surface conductive film 111, a rear surface conductive film 112, and a water absorption conductive layer 113 which generates conductance by water absorption and interposed between the two conductive films and is disposed on a coat of a diaper, inside of the coat of the diaper, or inside of the diaper. The electrode part is disposed on (a) a central and rear area of a lower part of a crotch, (b) a central and front area of the lower part of the crotch or a central and lowermost area of the lower part of the crotch, (c) a central and front area of the lower part of the crotch or central and lowermost area of the lower part of the crotch, and a central and rear area of the lower part of the crotch. The detection device comprises: a voltage generation part for intermittently applying voltage between the two conductive films; and a comparison part for comparing voltage drop between the two conductive films with reference voltage.

Description

  The present invention provides an excretion detection device for use in a diaper, which allows a caregiver or the like to easily know whether or not a care recipient needs to be excreted, and can further know whether excretion is feces or urine. About.

Recently, demand for disposable diapers is increasing due to an increase in the number of elderly people who need care (hereinafter referred to as care recipients).
A high molecular weight polymer is used as a urine absorber used in paper diapers.
For care recipients, in order to maintain health, water intake is required more than healthy adults, and sweating is rare. For this reason, the current situation is that the care recipient cannot know even if the absorption of urine by the polymer is saturated.
Further, in a care facility, when a care recipient has excreted stool, the care recipient often does not inform the caregiver that the defecation has occurred. In such a case, the caregiver knows that there was a bowel movement due to the smell of the stool, and as a result, the time for changing the diaper is delayed.

For this reason, a technique has been proposed in which a caregiver is informed of a time when a care recipient needs to change a disposable diaper.
For example, a technique is known in which a pigment that develops color with moisture is contained in a high molecular polymer, and when the color of the diaper changes color, the caregiver is notified of the time for replacement (Patent Document 1).
In addition, a technique is also known in which a caregiver is notified of a time when a paper diaper should be replaced by incorporating a moisture detection electrode pair into the paper diaper and measuring the resistance between the two electrodes (Patent Document 2).

Patent 3334233 Patent 3242358

The technique of Patent Document 1 (a technique for notifying surrounding people when to change a paper diaper) is effective for infant diapers.
That is, since the mother or the like can easily know that the infant's diaper has changed color, the mother or the like can easily know when the paper diaper should be replaced.
However, in the case of a care recipient, since it is practically impossible for the caregiver to always attend, a technique for notifying the time when the paper diaper should be changed by color change is not so effective.

  Moreover, although the technique of patent document 2 can detect the area | region where the urine spread for every cell, manufacture is very difficult and has not spread.

  In addition, since the techniques of Patent Documents 1 and 2 cannot detect stool and urine separately, the exchanging time is not the time when the stool is not excreted and it is not the time to replace the stool. If so, there are cases where mistakes are made.

  An object of the present invention is to provide an excretion detection device used for a diaper, which can know whether or not the wearer excreted, and also whether excretion is feces or urine.

The gist of the present invention is as follows.
(1)
An excretion detection device comprising: a detection device attached to a waist part of a diaper; and a sensor sheet attached from the detection device to a crotch center front area, a crotch center bottom area, or a crotch center rear area:
The sensor sheet has at least one electrode portion composed of a surface conductive film, a back surface conductive film, and a water-absorbing conductive layer that generates conductivity by water absorption interposed between the two conductive films, and includes a diaper skin and a diaper skin. Inside the diaper,
The electrode part is
(A) the crotch center rear area,
(B) the crotch center front area or the crotch center bottom area;
(C) provided in the crotch center front area or the crotch center lowermost area, and the crotch center rear area;
The detection device includes a voltage generation unit that intermittently applies a voltage between two conductive films, and a comparison unit that compares a voltage drop between the two conductive films with a reference voltage;
An excretion detection device characterized by that.

(2)
The excretion detection device according to claim 1, comprising a separation device:
The detection device includes a wireless transmission circuit that transmits a detection result,
The separation device includes a wireless reception circuit that receives a detection result received from the wireless transmission circuit, and an output circuit that displays or outputs the detection result.
An excretion detection device characterized by that.

(3)
An excretion detection device comprising a detection device attached to a waist part of a diaper and a sensor sheet attached from the detection device to a crotch center front area, a crotch center bottom area, or a crotch center rear area:
The sensor sheet has a sensor unit composed of a parallel conductor line or a U-shaped resistance line, and a water-absorbing conductive layer whose conductivity is changed by water absorption formed between the parallel conductor lines or between the U-shaped resistance line parallel lines, A surface on which the parallel conductor line or the U-shaped resistance line is formed is provided in the outer skin of the diaper, the inner side of the outer skin of the diaper, and the inside of the diaper so as to face the human body side;
The electrode part is
(A) the crotch center rear area,
(B) the crotch center front area or the crotch center bottom area;
(C) provided in the crotch center front area or the crotch center lowermost area, and the crotch center rear area;
The detection device includes a voltage generation unit that intermittently applies a voltage between two terminals of the feedback resistance line, and a comparison unit that compares a voltage drop of the feedback resistance line with a reference voltage;
An excretion detection device characterized by that.

(4)
4. The excretion detection device according to claim 3, comprising a separation device:
The detection device includes a wireless transmission circuit that transmits a detection result,
The separation device includes a wireless reception circuit that receives a detection result received from the wireless transmission circuit, and an output circuit that displays or outputs the detection result.
An excretion detection device characterized by that.

  According to the present invention, it is possible to know whether or not the wearer has excreted, and also whether the excretion is feces or urine.

1A to 1D are explanatory views showing a first embodiment of the excretion detection device of the present invention. 1A is a front view of the excretion detection device 1, FIG. 1B is a side view, FIG. 1C is an enlarged side view, and FIG. 1D is a top view of the detection device. FIG. 2 is a block diagram showing the detection device 12. FIG. 3 is a block diagram showing the separation device 41. FIG. 4 is a diagram illustrating a state before the diaper 5 to which the excretion detection device 1 is attached is attached to the wearer 6. FIG. 5 is a diagram illustrating a state after the diaper 5 to which the excretion detection device 1 is attached is attached to the wearer 6. 6A to 6D are explanatory views showing a second embodiment of the excretion detection apparatus of the present invention. 6A is a front view of the excretion detection device 2, FIG. 6B is a side view, FIG. 6C is an enlarged side view, and FIG. 6D is a top view of the detection device 22. FIG. 7 is a block diagram showing the detection device 22.

1A to 1D are explanatory views showing a first embodiment of the excretion detection device of the present invention.
1A is a front view of the excretion detection device 1, FIG. 6B is a side view, FIG. 6C is a side enlarged view, and FIG. 1D is a top view of the detection device.
In FIG. 1, the excretion detection device 1 includes a sensor sheet 11 and a detection device 12.
The sensor sheet 11 has the same flexibility as that of the diaper fabric. The sensor sheet 11 has a crotch center front area, a crotch center bottom area, and a crotch center bottom area on the inside of the outer skin of the diaper (see reference numeral 5 in FIGS. 4 and 5) It is attached to the area that extends to the crotch rear area.
The sensor sheet 11 includes a front surface conductive film 111, a back surface conductive film 112, a water absorbing conductive layer 113 that generates conductivity by water absorption, a front paper 114, a back paper 115, wiring 116, and a connector 118.

In the present embodiment, there are two electrode portions. The first electrode portion PA is provided in the crotch center front area A, and the second electrode portion PB is provided in the crotch center rear area B.
The electrode parts PA and PB are each composed of a front surface conductive film 111, a back surface conductive film 112, and a water-absorbing conductive layer 113 between the films 111 and 112.
The front surface conductive film 111 and the back surface conductive film 112 are made of a carbon film having many holes. The hole H makes it easy for urine to penetrate into the water-absorbing conductive layer 113 between the films 111 and 112. Moreover, the hole H can prevent the diaper 5 (refer FIG. 4, FIG. 5) from peeling.
The water-absorbing conductive layer 113 is a material whose conductivity increases in accordance with the amount of water absorption, and for example, a polymer can be used.

The front paper 114 and the back paper 115 are made of Japanese paper.
The surface paper 114 exists between the wearer's skin and the surface conductive films 111 and 112 and the water-absorbing conductive layer 113. Therefore, the wearer's skin does not touch the surface conductive film 111 or the water absorbing conductive layer 113.
An adhesive layer AD is formed on the back paper 115. A release paper RP is adhered to the adhesive layer AD.

The wiring 116 is provided between the front paper 114 and the water-absorbing conductive layer 113 and between the back paper 115 and the water-absorbing conductive layer 113. The surface of the wiring 116 is covered with an insulating material.
The connector 118 is made of a hard plate attached to the sensor sheet 11. The connector 118 is connected to the wiring 115 from the electrode pads a ₁ , a ₂ , b ₁ , b ₂ .

A slot SLT is formed in the casing of the detection device 12. The connector 118 of the sensor sheet 11 is attached to the slot SLT.
Further, the casing of the detection device 12 is provided with a power switch (ride switch SSW) and LEDs ₁ and ₂ .

FIG. 2 is a block diagram showing the detection device 12.
The detection device 12 includes a control unit 321, a voltage generation unit 322, a comparison unit 323, and an output unit 324.

The control unit 321 controls the voltage generation unit 322, the comparison unit 323, and the output unit 324.
A selector 3222, a selector 3231, and a selector 3234, which will be described later, are synchronously controlled by a control signal SLCT from the control unit 321.
The control unit 321 has a built-in timer and can detect excretion at regular intervals (for example, every 10 minutes).

The voltage generator 322 includes a power supply (V _s ) 3221 and a selector (SW) 3222. The voltage generator 322 drives the power source (V _s ) 3221 and the selector (SW) 3222 applies a step voltage, a pulse, a DC voltage, etc. to the first electrode part PA (311) and the second electrode part PB (312). Can be applied.

The comparison unit 323 can sequentially measure the current flowing through the electrode part PA (311) as _a voltage drop of the measurement resistor ra. The comparison unit 323 may be a current flowing through the second electrode portion PB (312), measured as a voltage drop across the measuring resistor r _b.
In FIG. 2, the resistance value of the first electrode portion PA is indicated by R _AX , and the resistance value of the second electrode portion PB is indicated by R _BX .

The comparison unit 323 includes current measurement resistors r _a and r _b , a selector (SW) 3231, an amplifier circuit (AMP) 3232, a comparison circuit (CMP) 3233, and a selector (SW) 3234.
When the selector 3231 selects the selected selector 3234 is the reference voltage V _ref1 measurement resistor r _a, the comparison circuit 3233 is able to detect the voltage drop of the amplified measuring resistor r _a by the amplifier circuit 3232 when the selector 3231 is a selector 3234 selects the measurement resistor r _a selected reference voltage V _ref2, the comparator circuit 3233 is able to detect the voltage drop of the measuring resistor r _b amplified by the amplifier circuit 3232

The output unit 324 _turns on the LEDs ₁ and ₂ in accordance with the comparison results V _c1 and V _c2 from the comparison unit 323, and at the same time, causes the separation device 41 shown in FIG. 3 to compare the results (defecation detection signal and urination detection signal). Can be sent out. The output unit 324 includes an LED drive circuit 3241 and a wireless transmission unit 3242.

  FIG. 4 is a diagram illustrating a state before the diaper 5 to which the excretion detection device 1 is attached is attached to the wearer 6.

  FIG. 5 is a diagram illustrating a state after the diaper 5 to which the excretion detection device 1 is attached is attached to the wearer 6.

Hereinafter, the operation of the first embodiment will be described.
The control unit 321 manages the measurement time using a timer.
At the measurement time, the control signal SLCT sets the selector 3222 and the selector 3231 to the first electrode part PA side, and sets the selector 3234 to the side where the reference voltage becomes V _ref1 .
The amplifier 3232 compares the amplified signal V _dtct1 with the reference voltage V _ref1 by the comparison circuit 3233. In FIG. 2, the resistance due to the water-absorbing conductive layer 113 is indicated by R _AX . Voltage drop across the resistor R _AX is detected as a voltage drop across the measuring resistor r _a.
This voltage drop is amplified by an amplifier 3232.

In FIG. 2, the current flowing through the electrode part PA is _expressed as V _dtct1 ≧ V _ref1
In this case, the LED driving circuit 3241 is driven and the LED ₁ is turned on, and a defecation detection signal is transmitted from the wireless transmission unit 3242 to the separation device 41 (see FIG. 3) wirelessly.
Also in the separation device 41, as will be described later, a defecation detection display or the like is made from the output unit 413.

Next, according to the control signal SLCT, the selector 3222 and the selector 3231 are set on the second electrode part PB side, and the selector 3234 is set on the side where the reference voltage becomes V _ref2 .
The amplified signal V _dtct2 is compared with the reference voltage V _ref2 by the comparison circuit 1233. In FIG. 2, the resistance due to the water-absorbing conductive layer 113 is indicated by R _BX . Voltage drop across the resistor R _BX is detected as a voltage drop across the measuring resistor r _b.
The voltage of the electrode part PB is amplified by the amplifier 3232, and the amplified signal V _dtct2 is compared with the reference voltage V _ref2 by the comparison circuit 3233.
V _dtct2 ≧ V _ref2
In this case, the LED driving circuit 3241 is driven and the LED ₂ is turned on, and a urination detection signal is transmitted from the wireless transmission unit 3242 to the separation device 41 in FIG. 3 wirelessly.

The wireless reception unit 412 receives the defecation detection signal from the wireless transmission unit 3242 described above, stores the reception time in the memory, and outputs an output instruction signal to the output unit 413.
The output unit 413 can notify a caregiver or the like that defecation / urination has occurred by using at least one LED or / and at least one melody sound.
The storage unit 414 is provided with a diaper exchange number display unit, and can display a past diaper exchange history (for example, how many diaper exchanges have been made).

6A to 6D are explanatory views showing a second embodiment of the excretion detection apparatus of the present invention.
6A is a front view of the excretion detection device 2, FIG. 6B is a side view, FIG. 6C is an enlarged side view, and FIG. 6D is a top view of the detection device 22.
In FIG. 6, the excretion detection device 2 includes a sensor sheet 21 and a detection device 22.
The sensor sheet 21 has the same flexibility as the diaper fabric, and, like the excretion detection device 1 shown in FIG. 1, the crotch center front area and the crotch center bottom area inside the diaper skin from the detection device 22. And is attached to an area extending from the crotch center rear area.
The sensor sheet 21 includes a first sensor resistance line 211, a second sensor resistance line 212, a water-absorbing conductive layer 213 that generates conductivity by water absorption, a front paper 214, a back paper 215, and a connector 218.

In the present embodiment, there are two sensor resistance wires. The first sensor resistance line 211 is provided in the crotch center front area A, and the second sensor resistance line 212 is provided in the crotch center rear area B.
The first sensor resistance line 211 and the second sensor resistance line 212 each have a U-shaped tip, and have a water-absorbing conductive layer 213 between U-shaped parallel portions. The water-absorbing conductive layer 213 is a material whose conductivity increases according to the amount of water absorption, and for example, a high molecular polymer can be used.

The front paper 214 and the back paper 215 are made of Japanese paper.
The surface paper 214 exists between the wearer's skin and the first sensor resistance line 211, the second sensor resistance line 212, and the water absorbing conductive layer 213. Therefore, the wearer's skin does not touch the surface first sensor resistance wire 211, the second sensor resistance wire 212, or the water-absorbing conductive layer 213.
An adhesive layer AD is formed on the back paper 215. A release paper RP is adhered to the adhesive layer AD.

The wirings 216 and 217 are provided between the front surface paper 214 and the water absorbing conductive layer 113 and between the back surface paper 215 and the water absorbing conductive layer 213. The surfaces of the wirings 216 and 217 are covered with an insulating material.
The connector 218 is made of a hard plate attached to the sensor sheet 21. A wiring 217 is connected to the connector 218.

A slot SLT is formed in the casing of the detection device 22. The connector 218 of the sensor sheet 21 is attached to the slot SLT.
Furthermore, the casing of the detection device 22 is provided with a power switch (ride switch SSW) and LEDs 1 and 2.

FIG. 7 is a block diagram illustrating a configuration of the detection device 22.
The configuration of the detection device 22 is substantially the same as the configuration of the detection device 22 shown in FIG. 2, but only the differences will be described below.

  In the detection device 22, the voltage generation unit 322 includes a power supply (Vs) 3221 and a selector (SW) 3222, and the voltage generation unit 322 drives the power supply (Vs) 3221, and the selector (SW) 3222 performs the first operation. A step voltage, a pulse, a DC voltage, or the like can be applied to the 1 sensor resistance line 211 and the second sensor resistance line 212.

The comparison unit 323 can sequentially measure the current flowing through the first sensor resistance line 211 as a voltage drop of the measurement resistor ra. Further, the comparison unit 323 can measure the current flowing through the second sensor resistance line 212 as a voltage drop of the measurement resistor rb.
In FIG. 7, the resistance value between the terminals of the first sensor resistance line 211 is indicated by RAY, and the resistance value between the terminals of the second sensor resistance line 212 is indicated by RBY.

Hereinafter, the operation of the second embodiment will be described.
The control unit 321 manages the measurement time using a timer.
At the measurement time, the control signal SLCT sets the selector 3222 and the selector 3231 to the first sensor resistance line 211 side, and sets the selector 3234 to the side where the reference voltage becomes Vref1.

Inter-terminal voltage of the first sensor resistance wire 211 is amplified by the amplifier 1232, the amplified signal V _Dtct1 is compared with the reference voltage V _ref1 by the comparison circuit 3233.
V _dtct1 ≧ V _ref1
In this case, the LED driving circuit 3241 is driven and the LED ₁ is turned on, and the defecation detection signal is transmitted from the wireless transmission unit 3242 to the separation device 41 described with reference to FIG.
Also in the separation device 41, as will be described later, a defecation detection display or the like is made from the output unit 413.

Next, according to the control signal SLCT, the selector 3222 and the selector 3231 are set on the second sensor resistance line 212 side, and the selector 3234 is set on the side where the reference voltage becomes V _ref2 .
The voltage between the terminals of the first sensor resistance line 211 is amplified by the amplifier 3232, and the amplified signal V _dtct2 is compared with the reference voltage V _ref2 by the comparison circuit 3233.
V _dtct2 ≧ V _ref2
In this case, the LED driving circuit 3241 is driven and the LED 2 is turned on, and a urination detection signal is transmitted from the wireless transmission unit 3242 to the separation device 41 by wireless.

The wireless reception unit 412 receives the defecation detection signal from the wireless transmission unit 3242 described above, stores the reception time in the memory, and outputs an output instruction signal to the output unit 413.
The output unit 413 can notify a caregiver or the like that defecation / urination has occurred by using at least one LED or / and at least one melody sound.
The storage unit 414 is provided with a diaper exchange number display unit, and can display a past diaper exchange history (for example, how many diaper exchanges have been made).

DESCRIPTION OF SYMBOLS 1, 2 Excretion detection apparatus 5 Diaper 6 Wearer 11, 21 Sensor sheet 12, 22 Detection apparatus 41 Separation apparatus 111 Surface conductive film 112 Back surface conductive film 113,213 Water absorption conductive layer 114, 214 Surface paper 115,215 Back surface paper 116, 216, 217 Wiring 118, 218 Connector 211 First sensor resistance line 212 Second sensor resistance line 322 Voltage generation unit 323 Comparison unit 324, 413 Output unit 3242, 412 Wireless reception unit 3222, 3223, 3231, 3234 Selector 3221 Power supply (V _s )
3232 Amplifier circuit (AMP)
3233 comparing circuit 3241 LED driving circuit _{a 1, a 2, b 1} , b 2 electrode pad LED _1, LED ₂ emitting diodes PA first electrode portion PB second electrode portions r _a, r _b measuring resistor SLT slots

Claims (4)

An excretion detection device comprising: a detection device attached to a waist part of a diaper; and a sensor sheet attached from the detection device to a crotch center front area, a crotch center bottom area, or a crotch center rear area:
The sensor sheet has at least one electrode portion composed of a surface conductive film, a back surface conductive film, and a water-absorbing conductive layer that generates conductivity by water absorption interposed between the two conductive films, and includes a diaper skin and a diaper skin. Inside the diaper,
The electrode part is
(A) the crotch center rear area,
(B) the crotch center front area or the crotch center bottom area;
(C) provided in the crotch center front area or the crotch center lowermost area, and the crotch center rear area;
The detection device includes a voltage generation unit that intermittently applies a voltage between two conductive films, and a comparison unit that compares a voltage drop between the two conductive films with a reference voltage;
An excretion detection device characterized by that. The excretion detection device according to claim 1, comprising a separation device:
The detection device includes a wireless transmission circuit that transmits a detection result,
The separation device includes a wireless reception circuit that receives a detection result received from the wireless transmission circuit, and an output circuit that displays or outputs the detection result.
An excretion detection device characterized by that. An excretion detection device comprising a detection device attached to a waist part of a diaper and a sensor sheet attached from the detection device to a crotch center front area, a crotch center bottom area, or a crotch center rear area:
The sensor sheet has a sensor unit composed of a parallel conductor line or a U-shaped resistance line, and a water-absorbing conductive layer whose conductivity is changed by water absorption formed between the parallel conductor lines or between the U-shaped resistance line parallel lines, A surface on which the parallel conductor line or the U-shaped resistance line is formed is provided in the outer skin of the diaper, the inner side of the outer skin of the diaper, and the inside of the diaper so as to face the human body side;
The electrode part is
(A) the crotch center rear area,
(B) the crotch center front area or the crotch center bottom area;
(C) provided in the crotch center front area or the crotch center lowermost area, and the crotch center rear area;
The detection device includes a voltage generation unit that intermittently applies a voltage between two terminals of the feedback resistance line, and a comparison unit that compares a voltage drop of the feedback resistance line with a reference voltage;
An excretion detection device characterized by that. 4. The excretion detection device according to claim 3, comprising a separation device:
The detection device includes a wireless transmission circuit that transmits a detection result,
The separation device includes a wireless reception circuit that receives a detection result received from the wireless transmission circuit, and an output circuit that displays or outputs the detection result.
An excretion detection device characterized by that.