JP4384701B2 - Urine sensor - Google Patents

Description

  The present invention relates to an automatic urine processing apparatus for automatically processing urine by being worn by a person who is difficult to control the timing of excretion of urine or to clean up excreted urine, such as a bedridden elderly person or a sick person. The present invention relates to a urine sensor capable of detecting excretion of urine.

  For the elderly and sick, it may be difficult to control the time of urine excretion by one's own will and to clean up after urine by oneself. Conventionally, in order to process such human urine, a urine receiver is applied around the urethral opening, and the urine collected in the suction part of the urine receiver is separated by a urine suction means such as a suction pump separate from the urine receiver. An automatic urine processing device that can be led to a urine tank has been proposed. The suction pump creates a pressure difference between the urine receiver and the urine tank by sucking air in the sealed urine tank, and the urine in the urine receiver can be guided to the urine tank by the pressure difference.

The urine receiver includes a urine sensor that detects that urine has been excreted and activates the suction pump. The urine sensor has a pair of electrodes, and when these electrodes are electrically connected by urine, electricity flows to the urine detection circuit and the suction pump can be operated. For example, this type of urine receiver disclosed in Japanese Patent Application Laid-Open No. 2004-267517 (Patent Document 1) has a surface sheet, a urine absorbing sheet, and a urine return suppressing sheet interposed between the both sheets, A pair of electrodes forming the urine sensor is disposed between the top sheet and the urine return suppressing sheet. According to this urine sensor, since the urine return suppression sheet prevents the urine from returning from the urine absorption sheet to the urine sensor, urine may not be absorbed quickly by the urine absorption sheet and may remain on it. No signal appears as if the urine was excreted due to the urine.
JP 2004-267517 A

  However, the electrode of the conventional urine sensor has a large area, and the entire area is exposed. Even if a small amount of urine remains on the surface sheet, the surface sheet and the electrode are in contact with each other. This could cause the suction pump to malfunction. In addition, body pressure is applied to the urine sensor due to a change in the posture of the wearer of the urine receiver, and the suction sheet may malfunction due to contact between the topsheet and the urine sensor.

  The present invention has been made in view of these problems of a conventional urine receiver, and has an object to prevent malfunction of a urine sensor included in the urine receiver.

  In order to solve the above-described problems, the present invention is directed to a urine absorption part to be worn in contact with the urethral opening and the surrounding skin, and interposed between the skin and the urine absorption part. A urine receiver is formed by a urine detector that detects that urine has been excreted from the urethral orifice, and the urine absorber and the urine detector are connected to a vacuum suction means that is separate from the urine absorber. The urine sensor used in the urine detection unit enables the urine to be sucked into the urine absorption unit when the vacuum suction means is operated based on a detection signal in the urine detection unit.

In this urine sensor, the present invention is characterized as follows. The urine sensor is formed on a thermoplastic synthetic resin film having a length direction, a width direction, and a thickness direction orthogonal to each other, a pair of electrodes formed on the surface of the film, and the surface And an electrically insulating coating covering the electrode. The film is formed with an opening at a central portion in the width direction of the film, and the pair of electrodes extend in the length direction and face each other with the opening interposed therebetween . Each of the electrodes has an electrical connection means to the vacuum suction means at one end in the length direction, and a plurality of electrodes formed on the insulating coating between both ends in the length direction. The through-hole is exposed so as to be in contact with the urine flowing into the through-hole. Opposite end portions of each of the pair of electrodes with respect to the one end portion are electrically connected via an electric resistor having an electric resistance larger than that of the electrodes. The electric resistor extends in the length direction while being covered with the insulating coating between the electrode and the edge of the opening.

In one embodiment, the electrical resistance of each of the electrodes is 150 KΩ or less, and the electrical resistance of the electrical resistor is 2 to 10 MΩ.

  In another embodiment, the urine sensor includes a stool detection electrode that is separate from the electrode and provided in parallel with each of the pair of electrodes, and the stool detection electrode is Although it is covered with an insulating coating, it has an exposed portion in the vicinity of the end facing the one end of the electrode, and feces excretion can be detected by the exposed portion.

In another embodiment, the electrode, the electric resistor, and the stool detection electrode are formed of any one of conductive ink and conductive paint.

The electrode of the urine sensor according to the present invention is formed on the surface of the thermoplastic synthetic resin film, and is located on both sides of the opening provided in the film, and is covered with an insulating coating. Yes. A plurality of through holes are formed in the coating, and the electrode has an exposed part in the through hole, so that the exposed part is wet with urine and the pair of electrodes are electrically connected. Thus, it is possible to reliably detect that urine is excreted, and the vacuum suction means does not malfunction. Further, means for detecting the presence or absence of disconnection of the pair of electrodes by electrically connecting the ends of the pair of electrodes via an electric resistor having an electric resistance larger than those of the electrodes. Can be used as The electrode has an exposed portion in a through-hole formed in the insulating coating, and the exposed portion does not expose the electrical resistor that detects the presence or absence of disconnection.

  In the present invention in which the excretion of feces is formed so as to be detectable, the trouble that the stool enters the urine-absorbing part and urine absorption by the urine-absorbing part becomes impossible can be solved.

  Details of the urine sensor according to the present invention will be described below with reference to the accompanying drawings.

  FIG. 1 is a schematic configuration diagram of an automatic urine processing apparatus 100 including a urine receiver 102 in which a urine sensor according to the present invention is used, and a vacuum suction means 100 a combined with the urine receiver 102. Note that the urine receiver 102 has an inner surface side facing the wearer's skin and an outer surface side opposite to the wearer's clothes. Shown in a broken state.

  The automatic urine processing apparatus 100 is an apparatus that can collect and process urine excreted by a wearer (not shown) in the urine receiver 102. The urine receiver 102 includes a tray-like container portion 112 that serves as a urine absorbing portion for receiving the excreted urine in contact with the skin in the vicinity of the wearer's urethral opening. It includes a vacuum suction means 100a including a joint member 104 connected to the section 112, a urinary tube 106, a urine tank 106a, a pump unit 108, an electric wiring 116, and the like.

  The pump unit 108 includes a suction pump (not shown) that operates based on a signal sent from the urine sensor 118 via the wiring 116. In the urine receiver 102, the urine guide tube 106 is connected to the urine discharge opening 114 formed in the peripheral wall portion of the container portion 112 via the joint member 104. A clip 120 for electrically connecting the electrodes 218a, 218b and the like (see FIG. 3) of the urine sensor 118 provided on the urine receiver 102 to the wiring 116 is attached to the tip of the wiring 116 extending from the pump unit 108. Yes. Such an automatic urine processing apparatus 100 detects that urine is excreted by the urine sensor 118, operates a suction pump included in the pump unit 108 by a signal based on the detection, and air in the urine tank 106a. The urine excreted by the wearer is sucked into the container portion 112, and the sucked urine is sucked through the joint member 104 and the urine guide tube 106 and collected in the urine tank 106a. it can.

  FIG. 2 is a diagram illustrating an example of a method for wearing the urine receiver 102. The urine receiver 102 is fixed to the inner surface side of the crotch belt portion 301 of the T-belt 300 using an adhesive, a mechanical fastener known by a trade name Magic Tape (registered trademark), or the like. Most of the container portion 112 of the urine receiver 102 extends in the vertical direction of the wearer's body, the inside faces the wearer's urethral opening and the surrounding skin, and the lower end portion gently curves to the anus. It is worn in an extended state. In the T-shaped belt 300, both end portions of the body belt portion 302 are detachably connected via a connecting means 303 such as a mechanical fastener, and one end portion of the crotch belt portion 301 is sewn to the body belt portion 302. The other end is connected to the body belt portion 302 through a mechanical fastener 304 so as to be separable. The urine receiver 102 can be worn using an appropriate means such as an open diaper, a pants-type diaper, a diaper cover, and incontinence patient pants, in addition to the illustrated wearing means.

  3 is a plan view showing the inner surface side of the urine receiver 102, FIG. 4 is a view showing a cut surface taken along line IV-IV in FIG. 3, and FIG. 5 is a cut surface taken along line V-V in FIG. 4 and 5, the members that should overlap in the thickness direction R of the urine receiver 102 are shown apart from each other except for some of them.

  3 and 4, the urine receiver 102 has a length direction P that matches the vertical direction of the wearer's body, and a width direction Q that is orthogonal to the length direction P, in the vicinity of both ends of the length direction P. Wide and narrow at the center. The urine receiver 102 also has a thickness direction R, and a liquid-impervious back sheet 122 and a non-breathable liquid-permeable sheet 124 are disposed above the container portion 112 in order from the lower side of the thickness direction R. A diffusion sheet 126, a cushion sheet 128, a urine sensor 118, a spacer 130 which is a spacer for protecting the urine sensor, a sheet filter 132 for protecting the urine sensor, a liquid-permeable skin resting sheet 134, and a breakwater 136. When the urine receiver 102 is worn, these are interposed between the urine receiver 102 and the wearer's skin.

  Further, when the urine receiver 102 is viewed in plan (see FIG. 3), the upper end portion and the lower end portion of the breakwater 136 are respectively covered with the first and second end sheets 138 and 140 (FIG. 3). reference).

  If stool is excreted while wearing the urine receiver 102 and the skin rest sheet 134 is covered with stool, the urine receiver 102 cannot suck urine. Therefore, the urine receiver 102 is provided with a stool sensor 144. In the fecal sensor 144, electrodes 143a and 143b are formed on the upper surfaces of the thermoplastic synthetic resin films 142c and 142d in FIG. 4 by aluminum vapor deposition or the like, and the films 142c and 142d are covered with two cover sheets 142a and 142b. ing. The cover sheet 142a is liquid-permeable, and moisture in the feces can permeate toward the electrodes 143a and 143b. In such a fecal sensor 144, the electrodes 143a and 143b extend in the length direction P in parallel with the urine detection electrodes 218a and 218b, and the lower end portion 145b in FIGS. ing. When the lower end portion 145b is stained with feces, moisture in the feces passes through the cover sheet 142a, the electrodes 143a and 143b are electrically connected, and current is supplied from the power source 116a (see FIG. 1) included in the wiring 116. A flow can be sent to an alarm (not shown) in the pump unit 108 to facilitate stool processing and urine receiver 102 replacement.

FIG. 6 is a plan view of the urine sensor 118 used in FIGS. 3 and 4, and the outline of the urine receiver 102 is indicated by a virtual line. The urine sensor 118 includes a film portion 260 formed of a thermoplastic synthetic resin film such as a polyester resin film, a pair of urine detection electrodes 218a and 218b formed on one surface of the film portion 260, and these electrodes 218a and 218b. And an insulative coating 170 covering most of the surface. The film portion 260 has a rectangular shape extending in the length direction P, and has a substantially rectangular opening 171 formed by cutting the center portion in the width direction Q long in the length direction P. Such a film portion 260 has an upper end portion 266 for gripping with the clip 120 above in FIG. 6, and a center line L ₁ -L that bisects the width of the urine sensor 118 below the upper end portion 266. ₁ has side portions 267a and 267b located on both sides of the _first portion, and further has a lower end portion 268a connected to the side portion 267a and a lower end portion 268b connected to the side portion 267b below. The lower end portion 268a and the lower end portion 268b are connected via a connecting portion 268c. The film part 260 is almost entirely covered with the insulating coating 170 on one side having the electrodes 218 a and 218 b, but the electrodes 218 a and 218 b are exposed at the upper end part 266. Further, a plurality of small circular portions formed on the side portions 267a and 267b and the lower end portions 268a and 268b are non-painted portions 169a and 169b formed as through holes in the covering 170. 170 is not formed, and the urine detector 175a or 175b of the electrode 218a or 218b is exposed.

FIG. 7 is a diagram showing a cut surface along the line VII-VII in FIG. 6. In addition to the urine detection electrode 218a, a disconnection detection electric resistor 250 is formed on the upper surface of the film portion 260 in the figure, and the urine detection portion 175a of the electrode 218a is exposed in the unpainted portion 169a. ing. However, the entire electric resistor 250 is covered with the insulating coating 170.

FIG. 8 is a plan view of the urine sensor 118 in a stage before the insulating coating 170 is formed. A urine detection electrode 218a is formed on one side of the film portion 260 so as to draw a substantially L shape at the side portion 267a and the lower end portion 268a. Further, a urine detection electrode 218b is formed so as to draw an L-shape in the opposite direction at the side portion 267b and the lower end portion 268b. Circular portions 175a and 175b formed in these electrodes 218a and 218b are exposed at the non-painted portions 169a and 169b in FIG. An electric resistor 250 for detecting disconnection is formed between the electrodes 218a and 218b. The electric resistor 250 is electrically connected to the lower end portions 173 and 174 of the urine detection electrodes 218a and 218b and extends along the edge of the opening 171 as shown in the drawing.

In such a urine sensor 118, a preferable film portion 260 is, for example, a polyester film having a thickness of 50 to 100 μm. The electrodes 218a and 218b can be obtained by printing a required shape on the film part 260 using conductive ink or conductive paint. The conductive ink and the conductive paint include, for example, 3 to 7% by weight of carbon black, 10 to 30% by weight of artificial graphite such as carbon graphite, and an appropriate amount of silver powder as a conductive material. Each of the preferred electrodes 218a and 218b is made to have a width of 0.5 to 2 mm and a resistance value of 150 KΩ or less, and the unpainted portions 169a and 169b have a diameter of 1 to 2 mm. The electrical resistor 250 for detecting disconnection can be obtained by printing a required shape on the film portion 260 using an ink containing 3 to 7% by weight of carbon black and 5 to 10% by weight of artificial graphite, for example. it can. The electrical resistor 250 has a resistance value far greater than that of the urine detection electrodes 218a and 218b. The preferred electrical resistor 250 has a width of 0.3 to 1 mm and a resistance value of about 2 to 10 MΩ. It is made to become.

When the urine sensor 118 of FIG. 6 is used in the urine receiver 102, the power supply 116a included in the electrical wiring 116 is always weak between the electrodes 218a and 218b and the electrical resistor 250 connected thereto via the clip 120. Current A is flowing. In the electric circuit 110 including the electric wiring 116, if the current A flows, it is determined that the urine detection electrodes 218a and 218b are normal. On the other hand, when the current A can no longer be detected, it is determined that the urine detection electrodes 218a and 218b have an abnormality such as disconnection, and a signal for prompting replacement of the urine sensor 118 is output from the pump unit 108 to the outside. be able to. In FIG. 6, the range indicated by the virtual line 176 is wetted by urine, and urine enters the non-painted portions 169a and 169b formed on the side portions 267a and 267b, and the urine detection portions 175a and 175b. When the electrode 218a on the side portion 267a and the electrode 218b on the side portion 267b are electrically connected via urine and the resistance between the electrodes 218a and 218b is smaller than the resistance of the electric resistor 250, electricity is It flows in urine with low resistance instead of the electric resistor 250 for detecting disconnection with high resistance. If the current B flowing through the urine is larger than the value of the current A flowing through the electric resistor 250, the electric circuit 110 captures this current change or a rapid change in the voltage or resistance value instead. Thus, it is possible to know that urine has been excreted. In the pump unit 108, the pump is operated based on a signal generated by the change to suck urine . If the value of the current B when flowing in the urine decreases, the electric circuit 110 stops the pump.

In the urine sensor 118 of FIG. 6, non-painted portions 169a and 169b for exposing the urine detection portions 175a and 175b are formed on both side portions 267a and 267b so as to be asymmetric with respect to the center line L ₁ -L _1. Yes. The non-painted portions 169a and 169b may be formed to be symmetric with respect to the center line L ₁ -L ₁ , but have the following effects when they are asymmetric as in the illustrated example. That is, the urine receiver 102 is folded in two in the length direction P while being worn, and a linear wrinkle that crosses the receiver 102 is generated in the skin resting sheet 134 that is wet with urine. When it is just over the unpainted portions 169a and 169b, the wet skin contact sheet 134 and the electrodes 218a and 218b are in contact with each other, and the pump unit 108 that has stopped after the suction of urine is mistaken. May start working again. However, if the non-painted portions 169a and 169b are asymmetric as in the illustrated example, it is easy to avoid such a malfunction. In addition, a plurality of non-coating portions 169a and 169b are formed in close proximity to each other at the lower end portions 268a and 268b of the film portion 260 and in the vicinity thereof. When the non-painted portions 169a and 169b are in such a manner, even if urine immediately after excretion does not go to the liquid-permeable sheet 124 and rapidly diffuses from the upper side to the lower side in the figure, the urine The receiver 102 can quickly suck the urine. The non-painted portions 169a and 169b are provided at appropriate portions of the side portions 267a and 267b in addition to such a mode, assuming the posture of the wearer when the urine receiver 102 is worn. be able to.

  FIGS. 9 and 10 are views similar to FIGS. 4 and 5 showing one embodiment of the urine receiver 102, but in a state where the overlapping members in the thickness direction R are separated from each other. The urine receiver 102 has a liquid-impermeable back sheet 122 on the outer surface side (lower surface side in the figure) of the container portion 112, and the back sheet 122 extends in the length direction P and the width direction Q from the periphery of the container portion 112. And extended. On the inner surface side of the container part 112, a bonding sheet 200, a liquid-impermeable sheet 124 with poor breathability, a cushion sheet 128, a urine sensor 118, a spacer 130, a filter 132, a skin pad sheet 134, The breakwater 136 overlaps in order as shown.

  The bonding sheet 200 is used to facilitate the bonding between the flange portion 152 of the container portion 112 and the liquid-permeable sheet 124. For example, when the container part 112 is made of polyethylene and the liquid-permeable sheet 124 is formed of rayon fiber, polypropylene fiber, polyester fiber or the like and is hard to melt compared to polyethylene, the container part 112, a material containing a resin having a melting temperature substantially equal to or lower than the melting temperature of the resin forming the resin 112, for example, a spunbond nonwoven fabric made of side-by-side composite fibers made of polyethylene and polypropylene. Used as a bonding sheet 200. When the polyethylene contained in the composite fiber interposed between the flange portion 152 and the liquid permeable sheet 124 is melted, the flange portion 152 and the liquid permeable sheet 124 cover the entire circumference of the flange portion 152 when pressed from the thickness direction R. Join easily. Such a bonding sheet 200 can be used not only to cover the entire flange portion 152 and the top opening of the container portion 112 as shown in the illustrated example, but also to cover only the flange portion 152.

The liquid-permeable sheet 124 in FIGS. 9 and 10 has the functions of the liquid-permeable sheet 124 and the diffusion sheet 126 in FIGS. 4 and 5. For example, rayon fibers having a fineness of 1 to 6 dtex and a length of 20 to 60 mm. Made of spunlace nonwoven with at least 40% by weight. The liquid-permeable sheet 124 can also contain thermoplastic synthetic fibers having a fineness of 1 to 6 dtex and a length of 20 to 60 mm up to 60% by weight. Pervious sheet 124, the air permeability, in the range of 0~100cc / cm ² / sec in a similar wet state and liquid-pervious sheet 124 of FIG. 4, in the dry state 20~200cc / ^cm 2 / The urine can be rapidly diffused by containing at least 40% by weight of rayon fiber in the range of seconds and also containing the rayon fiber as in the diffusion sheet 126 of FIG. Although it is preferable that the liquid permeable sheet 124 itself has a prescribed air permeability, it overlaps with the bonding sheet 200 covering the entire opening of the container portion 112 as shown in FIGS. In the urine receiver 102 when used in a state of being joined over at least the entire circumference of the flange portion 152, the overlapping liquid-permeable sheet 124 and the joining sheet 200 are defined as the liquid-permeable sheet 124 in FIGS. If the air permeability is satisfied, both the sheets 124 and 200 can be used in place of the liquid-permeable sheet 124 in FIGS.

  The cushion sheet 128 can be formed of the same material as the cushion sheet 128 of FIGS. 4 and 5, and has the same size as the liquid-permeable sheet 124.

  In the urine sensor 118, urine detection electrodes 218a and 218b are formed by applying a conductive paint on the inner surface of the film part 260 (see FIG. 9), and the film part 260 is a back sheet in the length direction P. It extends to the vicinity of both ends of 122. However, the film portion 260 has a pair of stool detection electrodes 143a and 143b (see FIG. 9) formed on the same surface as the surface on which the electrodes 218a and 218b are formed. Is different.

  The spacer 130 can be formed of the same material as the spacer 130 of FIGS. 4 and 5, and has the same size as the liquid-permeable sheet 124. The spacer 130 extends in the length direction P, but does not extend downward enough to cover the stool detection portions 144d and 144e (see FIG. 11) in the stool detection electrodes 143a and 143b.

  Each of the filter 132 and the skin contact sheet 134 can be formed of the same material as the filter 132 and the skin contact sheet 134 of FIGS. 4 and 5, and the filter 132 has the same size as the liquid-permeable sheet 124. On the other hand, the skin contact sheet 134 has the same dimension in the length direction P as the liquid-permeable sheet 124, but the dimension in the width direction Q is larger than that of the liquid-permeable sheet 124 and is substantially the same as the back sheet 122. It has been.

  An end sheet 138 and an end sheet 140 are provided at both ends in the length direction P of the urine receiver 102 (see FIG. 10). These two sheets 138 and 140 cover both ends (not shown) in the length direction P of the breakwater 136 in the same manner as in FIG.

  9 and 10, the liquid-permeable sheet 124, the cushion sheet 128, the urine sensor 118, the spacer 130, the filter 132, and the skin pad 134 that overlap each other are joined in the same manner as in FIGS. Yes. However, the back sheet 122 is joined to the skin-covering sheet 134 and other sheets above the back sheet 122, and preferably joined to the bottom outer surface of the container part 122. is doing. The leakage barrier 136 is joined to the skin contact sheet 134 and the back sheet 122 extending from the periphery of the skin contact sheet 134.

  The stool detection portions 144d and 144e of the stool detection electrodes 143a and 143b are covered with a non-woven fabric cover sheet 201 (see FIG. 10) that is permeable to stool moisture. A through hole 202 is formed in the end sheet 140 above the cover sheet 201 so that the end sheet 140 does not cover the stool detection portions 144d and 144e. The through hole 202 is positioned near the anus of the wearer of the urine receiver 102.

FIG. 11 is a partially cutaway plan view of the urine sensor 118 used in the urine receiver 102 shown in FIGS. The urine sensor 118 has a pair of urine detection electrodes 218a and 218b, a pair of stool detection electrodes 143a and 143b, and a disconnection detection sensor on the inner surface of a film portion 260 formed of a liquid-impervious thermoplastic synthetic resin film. The most part of the electrodes 218a, 218b, 143a, 143b and the whole of the electric resistor 250 for detecting disconnection are covered with a coating 170 made of an insulating paint. A portion of the coating 170 is shown broken. In the film portion 260, openings 171 and 172 arranged in the length direction P are formed in the center portion in the width direction Q. A bridge 183 is formed between the openings 171 and 172 for preventing the film portion 260 from being deformed. In addition, the pair of electrodes 218a and 218b and the pair of electrodes 143a and 143b are formed so as to face each other with the openings 171 and 172 interposed therebetween, and the disconnection detection electric resistor 250 is a pair of urine detection electrodes. The ends of 218a and 218b are connected to each other and extend along the edges of the openings 171 and 172. In FIG. 11, urine detection electrodes 218a and 218b have urine detection portions 175a and 175b except for a non-painted portion 169a formed on the covering 170, and stool detection electrodes 143a and 143b are urine detection electrodes. Stool detectors 144d and 144e that are not covered by the covering 170 are provided near the lower ends of 218a and 218b. The urine detectors 175a and 175b and the feces detectors 144d and 144e are formed substantially symmetrically with respect to the center line L ₁ -L ₁ . Further, connector portions 218c and 218d are formed at the upper ends of the urine detection electrodes 218a and 218b, and connector portions 244a and 244b are formed at the upper ends of the feces detection electrodes 143a and 143b. These connector portions 218c, 218d and 244a, 244b are gripped by the clip 120 of FIG. When the urine detection units 175a and 175b are connected by urine between the pair of urine detection electrodes 218a and 218b, the urine is interposed between the urine detection electrodes 218a and 218b in the same manner as the urine sensor 118 in FIG. Thus, a current flows and the pump unit 108 can be operated. In addition, when the stool detectors 144d and 144e are connected by stool or moisture contained in the stool between the pair of stool detection electrodes 143a and 143b, a current flows and is the same as in the case of the urine receiver 102 in FIGS. The pump unit 108 can notify that the stool has been defecation.

Note that a weak current always flows through the electrical resistor 250 for disconnection detection similarly to the urine sensor 118 of FIG. 8, and when the urine detection electrodes 218a and 218b are damaged and disconnected, A change in current that occurs sometimes can be captured, and a disconnection alarm (not shown) attached to the pump unit 108 can be activated to notify the disconnection and prompt the user to replace the urine receiver 102.

  According to the present invention, it is possible to produce a urine receiver capable of efficiently and quickly sucking urine.

The schematic block diagram of the automatic urine processing apparatus containing a urine receiver. The figure which shows the wearing condition of a urine receiver. The top view of a urine receiver. The figure which shows the IV-IV line | wire cut surface of FIG. The figure which shows the VV line | wire cut surface of FIG. The top view of a urine sensor. The figure which shows the VII-VII line cut surface of FIG. The top view of the urine sensor in which the insulating coating is not given. The figure similar to FIG. 4 which shows the one aspect | mode of a urine receiver. The figure similar to FIG. 5 which shows the one aspect | mode of a urine receiver. The figure similar to FIG. 6 which shows an example of an embodiment.

100a Suction means 102 Urine receiver 112 Urine sucking part (container part)
118 Urine sensor 143a, 143b Stool detection electrode 169a, 169b Through hole (exposed part)
170 Cover 171 Opening 172 Opening 175a, 175b Urine detector 218a, 218b Electrode (Urine detection electrode)
218c, 218d One end (connector part)
250 electric resistor 260 film P length direction Q width direction R thickness direction

Claims (4)

A urine absorption part worn in contact with the urethral opening and the surrounding skin, and a urine detection part for detecting that urine is excreted from the urethral opening interposed between the skin and the urine absorption part; A urine receiver is formed by connecting the urine absorption part and the urine detection part to a vacuum suction means separate from the urine absorption part and operating the vacuum suction means based on a detection signal in the urine detection part Then, a urine sensor used in the urine detection unit that allows the urine to be sucked into the urine absorption unit,
The urine sensor is formed on a thermoplastic synthetic resin film having a length direction, a width direction and a thickness direction orthogonal to each other, a pair of electrodes formed on the surface of the film, and the surface The film is formed with an opening at a central portion in the width direction of the film, and the pair of electrodes extend in the length direction and face each other with the opening interposed therebetween. is formed, each of said electrodes, one end portion in the longitudinal direction has an electrical connection means to said vacuum suction means, between both ends in the longitudinal direction, formed on said insulating covering The exposed plurality of through-holes are exposed so as to be in contact with the urine flowing into the through-holes, and the opposed end portions of each of the pair of electrodes with respect to the one end portion are more than the electrodes. Electrically connected via an electric resistor having a threshold electric resistance, and the electric resistor extends in the length direction while being covered with the insulating coating between the electrode and the edge of the opening. The urine sensor characterized by comprising:   The urine sensor according to claim 1, wherein the electrical resistance of each of the electrodes is 150 KΩ or less, and the electrical resistance of the electrical resistor is 2 to 10 MΩ.   The urine sensor has a stool detection electrode that is separate from the electrode and is provided in parallel with each of the pair of electrodes, and the stool detection electrode is covered with an insulating coating. The urine sensor according to claim 1, wherein the urine sensor has an exposed portion in the vicinity of an opposite end portion of the electrode to the one end portion, and feces excretion can be detected by the exposed portion.   The urine sensor according to any one of claims 1 to 3, wherein the electrode, the electric resistor, and the stool detection electrode are formed of any one of conductive ink and conductive paint.

Images