JP5129073B2 - Urine receiver - Google Patents

Description

  The present invention relates to a urine receiver that is worn by a person who is difficult to clean up urine by himself, such as a bedridden elderly person, and automatically processes urine.

Urine processing apparatuses that can be worn by bedridden elderly people and automatically process urine are known in the art. For example, a urine receiver disclosed in Japanese Patent Application Laid-Open No. 2006-26108 (Patent Document 1) has a suction part that collects the wearer's urine, and a urine guide tube extending from the suction part is connected to the vacuum tank. The suction part has an opening covered with a water permeable sheet, and a pair of electrodes spaced apart and parallel to each other are provided on the inner surface side of the water permeable sheet. When the urine receiver is worn and the pair of electrodes are electrically connected to each other by urine, an electric signal for operating the vacuum pump is output, and urine is discharged from the suction portion toward the urine guide tube.
JP 2006-26108 A

  In the urine receiver described in Patent Document 1, when a pair of electrodes are covered with a water permeable sheet and urine is excreted by the wearer of the urine receiver, the urine is permeable to the water permeable sheet or other water permeable sheets overlapping this sheet. It spreads so that a pair of electrode may be electrically connected through a sheet | seat. However, depending on the posture of the wearer, the urine may not be so spread, and the vacuum pump cannot be operated quickly even if urine is excreted.

  An object of the present invention is to improve a conventional urine receiver so that when urine is excreted, a pair of electrodes can be electrically connected quickly by the urine.

  In order to solve the above-mentioned problems, the present invention is directed to a urine discharge penetrating through the peripheral wall portion of a leak-proof container having a bottom portion, a peripheral wall portion, and a top opening defined by the peripheral wall portion. The conduit is formed to be connectable to a urine suction means separate from the container, and the top opening is covered with a plurality of liquid permeable sheets overlapping each other, and the plurality of liquid permeable sheets A pair of electrodes extending in one direction in parallel and spaced apart from each other are provided therebetween, and the pair of electrodes is electrically connected via urine contained in any of the plurality of liquid-permeable sheets. A urine receiver capable of sucking urine excreted by a wearer of the container into the container from the top opening and discharging the sucked urine from the duct.

In such a urine receiver , the present invention is characterized as follows. Any one of the plurality of liquid-permeable sheets and located outside the pair of electrodes in the depth direction of the container is formed of a nonwoven fabric containing a thermoplastic synthetic fiber, and the depth An outer surface facing outward in the direction and an inner surface facing inward in the depth direction. The outer surface is formed with undulations in which peaks and valleys appear alternately and repeatedly in the one direction, and the peaks and the valleys extend in a direction intersecting the one direction. Is in a state of crossing the electrodes.

  In one embodiment of the present invention, the sheet on which the undulation is formed on the outer surface is in close contact with the liquid-permeable sheet having a flat inner surface and facing the inner surface.

  In one embodiment of the present invention, in the sheet on which the undulation is formed on the outer surface, the inner surface is parallel to the outer surface, and the inner surface of the valley portion faces the inner surface. Is in close contact with the adhesive sheet.

  In one embodiment of the present invention, the top portion of the peak portion is hydrophobic, and the bottom portion of the valley portion is hydrophilic.

  In another embodiment of the present invention, the nonwoven fabric includes a plurality of thermoplastic synthetic fibers extending in a direction intersecting the one direction at the valley portion.

  In the urine receiver according to the present invention, one of the liquid-permeable sheets covering a pair of electrodes is formed of a nonwoven fabric, and peaks and valleys appear alternately and repeatedly in the direction in which the electrodes extend on the outer surface of the nonwoven fabric. The crests and troughs extend in a direction crossing the direction in which the electrodes extend and cross the pair of electrodes. When the urine excreted by the wearer of the urine receiver flows into the trough, the urine flows along the trough and can quickly electrically connect the pair of electrodes. As a result, the urine suction means to which the urine receiver is connected also operates quickly, facilitating the suction of urine into the container part and the discharge of urine from the container part.

  The details of the urine receiver according to the present invention will be described below with reference to the accompanying drawings.

  FIG. 1 is a schematic view of an automatic urine processing apparatus 100 including a urine receiver 102 according to the present invention and a urine suction means 100a using vacuum pressure to which the urine receiver 102 is connected. The urine receiver 102 has a skin contact side directed toward the skin of a wearer (not shown) and a clothing contact side opposite to the skin contact side directed toward the wearer's clothing. The contact side member is shown partially broken.

  The automatic urine processing apparatus 100 can automatically collect the urine excreted by the wearer in the urine receiver 102. The urine receiver 102 includes a container portion 102a that collects excreted urine in contact with the skin near the wearer's urethral opening, and a urine detector 102b that detects that urine is excreted, and includes a vacuum urine suction means 100a. Includes a joint member 104 connected to the urine receiver 102, a urine guide tube 106, a urine tank 106a, a pump unit 108, an electrical 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 detection unit 102b via the wiring 116. In the urine receiver 102, the urine guide tube 106 is connected to the opening 114 of the urine discharge conduit formed in the peripheral wall portion 112c of the container 112 in the container portion 102a via the joint member 104. A clip 120 for electrically connecting the electrodes 218a and 218b (see FIGS. 3 and 4) of the urine sensor 118 provided in the urine detection unit 102b to the wiring 116 is attached to the tip of the wiring 116 extending from the pump unit 108. It has been. The 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 based on a signal based on the detection, and air in the urine tank 106a. , The urine can be sucked into the container 112, and the sucked urine can be further sucked through the joint member 104 and the urine guide tube 106 and collected in the urine tank 106a.

  FIG. 2 is a diagram illustrating an example of a method of wearing the urine receiver 102, and the clip 120 is on the ventral side. The urine receiver 102 is fixed to the inner surface side of the crotch belt portion 301 of the T-shaped belt 300 that is a wearing means by using an adhesive, a mechanical fastener known by a trade name Magic Tape (registered trademark), or the like. Most of the container 112 of the urine receiver 102 extends in the vertical direction on the front side of the wearer's body, and the inside faces the wearer's urethral opening and the surrounding skin, and the lower end portion in FIG. While being gently curved along the inner surface of 301, it is worn in a state of extending toward the anus. In the T-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 stitched 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, 4, and 5, FIG. 3 is a plan view showing the skin contact surface side of the urine receiver 102 facing the wearer's (not shown) skin, and FIG. 4 is taken along line IV-IV in FIG. 3. 5 is a diagram showing a cut surface along the line V-V in FIG. 3. In FIGS. 4 and 5, each member to be overlapped in the thickness direction R of the urine receiver 102 is shown. It is shown spaced apart from each other with the exception of some. The thickness direction R can also be referred to as the depth direction of the container 112. In the present invention, the outside in the depth direction means the direction from the opening 112a of the container 112 to the outside of the container 112 in FIG. 4, and the inside in the depth direction means the direction from the opening 112a to the inside of the container 112. Means direction.

  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. The width is narrow. The urine receiver 102 also has a thickness direction R. In the upper part of the container 112 in FIG. A plurality of sheet-like members composed of a conductive sheet 124, a diffusion sheet 126, a cushion sheet 128, a urine sensor 118, a sheet-like spacer 130, a sheet-like filter 132, and a liquid-permeable skin-contacting sheet 134 Has a breakwater 136 overlaid. The leak-proof sheet 122, the air-impermeable sheet 124, and the diffusion sheet 126 are integrated with the container 112 to form a container portion 102a. In addition, the cushion sheet 128, the urine sensor 118, the spacer 130, the filter 132, and the skin pad 134 overlap each other to form the urine detection unit 102b.

  The container 112 has a tray shape having a bottom portion 112b, a peripheral wall portion 112c, and a top opening 112a and is leak-proof, and is made of a soft elastic material such as soft polyethylene or silicon rubber. The container 112 is also flexible so that it can be bent in both the length direction P and the width direction Q, but is designed to withstand deformation caused by negative pressure that acts when urine is sucked by a suction pump. It has been. A leak-proof sheet 122 is joined to the peripheral flange portion 152 of the container 112 through an adhesive 112d in a watertight state.

  The leak-proof sheet 122 spreads outside the container 112 and prevents urine from leaking from the urine receiver 102. The leak-proof sheet 122 can be formed of a thermoplastic synthetic resin film, a composite sheet of the film and a non-woven fabric, or the like, and the urine receiver 102 in FIG. 1 uses a soft polyethylene film having a thickness of 30 μm. In addition, when the urine receiver 102 does not need the leakproof property in the peripheral part of the container 112, it is also possible to omit this leakproof sheet 122 and to implement this invention.

The non-breathable sheet 124 has high liquid permeability but does not allow air to pass through almost or at all, and covers the opening 112a at the top of the container 112 as shown in FIG. On the other hand, they are joined from above via a hot melt adhesive 124a. The container 112 having the non-breathable sheet 124 easily becomes negative pressure when the suction pump of the pump unit 108 is operated, and can quickly suck the urine excreted toward the skin pad 134. Air-impermeable sheet 124, for example, an SMS nonwoven fabric consisting of 22 g / ^{m 2} spunbond nonwoven fabric and 10 g / ^{m 2} meltblown non-woven fabric and 22 g / ^{m 2} spunbond nonwoven, preferably hydrophilic treatment with a surfactant Can be used. The air permeability of the non-breathable sheet 124 is 0-100 cc / cm ² / sec in a wet state when measured according to method A of the air permeability measurement method defined in Section 6.27.1 of JIS L 1096. Preferably, it is in the range of 0 to 50 cc / cm ² / sec. Moreover, in a dry state, it is 20 to 200 cc / cm ² / second, preferably 20 to 100 cc / cm ² / second, and more preferably 20 to 50 cc / cm ² / second. The wet state when measuring the air permeability means a state where the moisture content of the non-breathable sheet 124 calculated by the following formula (1) is 100% or more, and the dry state means the non-breathable property. The state of the sheet 124 when the sheet 124 is left in a room at 20 ° C. and RH 50% for 24 hours or more is meant.

  Moisture content = (wet sheet weight−dry sheet weight) / (dry sheet weight) Formula (1)

  The diffusion sheet 126 is formed of a liquid-permeable sheet piece such as a non-woven fabric containing hydrophilic fibers such as rayon fibers. When the urine is excreted, the diffusion sheet 126 is quickly diffused above the breathable sheet 124. It is used to wet the breathable sheet 124 over a large area. When the air-impermeable sheet 124 becomes wet, it becomes easy to suck the urine into the container 112 under a negative pressure. It is preferable that the diffusion sheet 126 is intermittently bonded to the air-impermeable sheet 124 so as not to impede liquid permeability.

The cushion sheet 128 is formed of a liquid-permeable sheet piece such as a thermal bond nonwoven fabric having a basis weight of 20 to 30 g / m ² , for example, and can quickly infiltrate urine. The urine present in the adhesive sheet 124 is prevented from flowing back toward the urine sensor 118. The cushion sheet 128 can also be placed at a predetermined position in the urine receiver 102 during the manufacturing process of the urine receiver 102 by previously stacking sheet members such as the urine sensor 118, the spacer 130, and the filter 132 on the cushion sheet 128. It becomes a carrier member for placing. The cushion sheet 128 is preferably joined intermittently to the diffusion sheet 126 so as not to impede mutual liquid permeability.

  The urine sensor 118 can be obtained, for example, by printing an electrode of a required shape on a synthetic resin film with conductive ink, and the details of the structure are as described later. The urine sensor 118 is interposed between the air-impermeable sheet 124 of the plurality of liquid-permeable sheets 124, 126, 128, 130, 132, and 134 that covers the opening 112 a of the container 112 and the skin rest sheet 134. Thus, in the illustrated example, the cushion sheet 128 and the spacer 130 are sandwiched. The urine sensor 118 can be bonded to the cushion sheet 128.

  The spacer 130 is formed of a net-like liquid-permeable sheet. In the urine receiver 102, urine may remain on the skin contact sheet 134 even after the urine is sucked, and the skin contact sheet 134 may be in a wet state due to the urine. Then, the skin contact sheet 134 may directly or indirectly contact the urine sensor 118 under the action of body pressure or the like, causing the urine sensor 118 to malfunction. The spacer 130 is a means for separating the urine sensor 118 and the filter 132 in the thickness direction R in order to prevent such a malfunction, has no urine absorption capability, is water repellent, and has poor breathability. It has higher air permeability and liquid permeability than the sheet 124, and its thickness does not change even when subjected to body pressure. Such a spacer 130 can be made of a net having a thickness of 0.5 to 1 mm formed of a flexible synthetic resin such as ethylene vinyl acetate, and inhibits the liquid permeability of the cushion sheet 128. It is preferable to join so that it does not occur.

  The filter 132 is for preventing a situation in which a solid content in urine adheres to the urine sensor 118 and the urine sensor 118 is permanently energized, and has a higher ventilation than the air-impermeable sheet 124. It is formed by a sheet piece having a property and liquid permeability, more preferably a non-woven piece. The filter 132 can be intermittently joined to the spacer 130 so as not to impede mutual liquid permeability.

The skin application sheet 134 has an upper surface 134 a and a lower surface 134 b, and the lower surface 134 b is in close contact with the upper surface of the filter 132. When the urine receiver 102 is worn, the upper surface 134a contacts the skin while facing the urethral opening of the wearer and the skin in the vicinity thereof. This skin contact sheet 134 is formed of a sheet piece having flexibility and liquid permeability, such as a thermal bond nonwoven fabric having a basis weight of 15 to 25 g / m ² , for example. Like the cushion sheet 128, the skin rest sheet 134 is capable of instantaneously penetrating urine at the initial stage of urination, and does not impede mutual liquid permeability with respect to the filter 132. It is preferable that they are joined intermittently. The skin application sheet 134 may be hydrophilic or water repellent.

  As shown in FIGS. 3 and 4, the leakage barrier 136 forms a pair of left and right, and prevents urine from leaking from the urine receiver 102 by flowing in the width direction Q over the skin rest sheet 134. it can. In the leakage breaker 136, the outer edge 136c located closer to the outer side of the urine receiver 102 is joined to the skin rest sheet 134, while the inner edge 136d located closer to the inner side is joined to the skin rest sheet 134. Instead, an elastic member 136b (see FIG. 4) such as a rubber thread is attached in a state of extending in the length direction P. When the urine receiver 102 is worn and curved in the length direction P as shown in FIG. 1 and the elastic member 136b contracts, the inner edge 136d of the leakage barrier 136 is separated from the skin pad 134. Stand up. The breakwater 136 is formed of a flexible thermoplastic synthetic resin film, a composite sheet of the film and a nonwoven fabric, or the like, and preferably impermeable to liquid. When the urine receiver 102 is viewed in plan, the leakage barrier 136 (see FIG. 3) is covered with the first and second end sheets 138 and 140 at the upper end and the lower end, respectively.

If stool is excreted while wearing the urine receiver 102 and the skin resting sheet 134 is covered with stool, the urine receiver 102 may not be able to detect urine or be able to aspirate urine. is there. In order to prevent this, as shown in FIGS. 3, 4, and 5, a stool sensor 144 is provided in the urine receiver 102. In the fecal sensor 144, electrodes 143a and 143b are formed on the upper surfaces of the thermoplastic synthetic resin films 142c and 142d by vapor deposition of aluminum or the like, and the films 142c and 142d are covered with two cover sheets 142a and 142b. The cover sheet 142a is liquid-permeable, and moisture in the feces can permeate toward the electrodes 143a and 143b. In such a feces sensor 144, the electrodes 143a, 143b urine detecting electrodes 218a, in parallel to 218b extend the length direction P, the lower end portion 145b in FIG. 3, 5 downwardly from the second end sheet 140 It is extended. 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. It can flow and send a signal to an alarm (not shown) in the pump unit 108 to prompt the caregiver to process the stool and replace the urine receiver 102.

FIG. 6 is a plan view of the urine sensor 118 used in FIGS. 3, 4, and 5, and the outline of the urine receiver 102 is indicated by a virtual line. The urine sensor 118 covers a film part 260 formed of a synthetic resin film, a pair of urine detection electrodes 218a and 218b formed on one surface of the film part 260, and most of these electrodes 218a and 218b. And an insulating coating 170. 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 on both sides, 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. At the upper end 266 of the film part 260, the electrodes 218a and 218b are exposed. A plurality of small circular portions formed on the insulating coating 170 at the side portions 267a and 267b and the lower end portions 268a and 268b are non-painted portions 169a and 169b, and the coating 170 is provided here. It is not formed, and the urine detection site 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 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. Yes. The entire resistor 250 is covered with an insulating coating 170.

FIG. 8 is a plan view of the urine sensor 118 with the insulating coating 170 peeled off. 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. A disconnection detecting resistor 250 is formed between the electrodes 218a and 218b. The 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 figure.

In such a urine sensor 118, a polyester film having a thickness of 50 to 100 μm is used for the preferred film portion 260. 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 disconnection detecting resistor 250 can be obtained by printing a required shape on the film portion 260 using an ink containing, for example, 3 to 7% by weight of carbon black and 5 to 10% by weight of artificial graphite. The resistor 250 has a resistance value far higher than that of the urine detection electrodes 218a and 218b, and the preferable resistor 250 has a width of 0.3 to 1 mm and a resistance value of about 2 to 10 MΩ. Made as follows. When the resistor 250 is the same as the ink used for the electrodes 218a and 218b and has a high conductivity or is wide so that printing can be easily performed, the resistor 250 has a vertical direction as shown in the illustrated example. It is possible to extend the entire length as much as possible by extending along the edge of the opening 171 that is long to P, thereby increasing the resistance value.

When the urine sensor 118 of FIG. 6 is used in the urine receiver 102, a weak current is always generated between the electrodes 218a and 218b and the resistor 250 connected to the electrodes 218a and 218b from the power source 116a included in the electrical wiring 116 via the clip 120. 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, when the range indicated by the virtual line 176 is wetted by urine, the 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. The electrode 218a on the side portion 267a and the electrode 218b on the side portion 267b are electrically connected via urine. When the resistance between the electrodes 218a and 218b becomes smaller than the resistance of the resistor 250, electricity flows through the urine having a low resistance instead of the resistor 250 having a high resistance . If the current B flowing through the urine is larger than the value of the current A flowing through the resistor 250, the electric circuit 110 captures the change in the current or a rapid change in the voltage or resistance value instead. It is possible to know that urine has been excreted. The pump unit 108 operates the pump based on a signal generated by the change to suck urine, and stops the pump when the resistance between the electrodes 218a and 218b increases.

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. it is but non-painted parts 169a, 169b are those that may be formed to be symmetrical about the center line _L 1 -L _1. 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 face the breathable sheet 124 and rapidly diffuses from the upper side to the lower side of the drawing, 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.

  9 and 10 are a perspective view of a sheet piece 400 which is an example of the skin contact sheet 134, and a cross-sectional view taken along the line XX in the perspective view. The sheet piece 400 includes 80 to 100% by weight of a hydrophobic thermoplastic synthetic fiber 407 and 20 to 0% by weight of a water absorbent fiber such as rayon fiber, and the fibers are welded to each other or mechanically entangled. The outer surface 400a is directed to the wearer's skin side of the urine receiver 102, and the inner surface 400b is directed to the urine sensor 108 side. The length direction, the width direction, and the thickness direction. Are the same in the length direction P, the width direction Q, and the thickness direction R in the urine receiver 102. Note that the outer surface 400a and the inner surface 400b can be referred to as an upper surface and a lower surface in FIG.

  The outer surface 400a of the sheet piece 400 has undulations that appear so that peaks 401 and valleys 402 alternately repeat in the longitudinal direction P. The peaks 401 and valleys 402 are parallel to each other and have a width. It extends in the direction Q. The inner surface 400 b of the sheet piece 400 is flat and is in close contact with the filter 132. Such a sheet piece 400 is used such that the crest 401 and the trough 402 cross the pair of electrodes 218a and 218b in the urine sensor 118, and preferably the edges 403 on both sides in the width direction Q are the urine receivers. It is used so that it may be located in the inside of the breakwater 136 (refer FIG. 4) provided in the both sides of 102. FIG.

  In the urine receiver 102 in which the sheet piece 400 is used as the skin patch sheet 134, when the urine receiver is in a worn state and urine is excreted toward the sheet piece 400, the urine easily collects in the valley portion 402. In 402, it is easier to spread in the width direction Q than in the vertical direction P. Therefore, in the urine receiver 102, the pair of electrodes 218a and 218b are electrically connected quickly via the urine, and the urine receiver 102 can quickly suck urine. The urine receiver 102 that utilizes the action of the valley portion 402 in the sheet piece 400 diffuses urine in the width direction Q even when the wearer is lying on the side, so that the pair of electrodes 218a and 218b can be quickly electrically connected. It is particularly excellent in that it can be connected.

The urine detection sites 175a and 175b (see FIG. 6) in the electrodes 218a and 218b used in combination with the sheet piece 400 acting in this way are formed so as to be symmetric with respect to the center line L ₁ -L ₁ . Is preferred. The sheet piece 400 also has a basis weight of 15 to 80 g / m ² , and the plurality of hydrophobic thermoplastic synthetic fibers 407 used for the sheet piece 400 has a fineness of 1 to 8 dtex and a fiber of 20 to 80 mm. It is preferable that most of the thermoplastic synthetic fibers 407 that are long and located in the valley portion 402 are oriented in the width direction Q. Such a sheet piece 400 can be obtained by heating and pressurizing a nonwoven fabric such as a thermal bond nonwoven fabric with a pair of upper and lower molds. Use an upper mold with a crest and a trough, and use a flat one for the lower mold, and the nonwoven fabric should have a machine direction when manufacturing it in the direction in which the trough extends. By making it match, the thermoplastic synthetic fiber oriented in the machine direction in the nonwoven fabric can be oriented in the width direction Q. Furthermore, the sheet piece 400 may be promoted to move urine from the peak portion 401 to the valley portion 402 by performing a hydrophilic treatment so that the hydrophilicity is higher in the valley portion 402 than in the peak portion 401. it can. Sheet piece 400 can also be made so that the top of peak 401 is water repellent and the bottom of trough 402 is hydrophilic.

  FIG. 11 is a view similar to FIG. 10 for a sheet piece 400 having a different form from the sheet piece 400 in FIGS. The sheet piece 400 in FIG. 11 has a substantially uniform thickness as a whole, the inner surface 400b is parallel to the outer surface 400a, and the peak portion 411 corresponding to the peak portion 401 on the outer surface 400a and the valley portion 402 Corresponding troughs 412. The inner surface 400b in the valley 402 is joined to the filter 132 facing the inner surface 400b by adhesion or welding. The sheet piece 400 and the filter 132 are intermittently joined in the width direction Q, and are in close contact with each other so as to facilitate urine permeation between the joined parts. Since a tunnel 405 extending in the lateral direction Q is formed between the sheet piece 400 and the filter 132, the urine receiver 102 having the aspect of FIG. 11 is compared with the urine receiver 102 having the aspects of FIGS. The air permeability in the lateral direction Q is high. The sheet piece 400 in the illustrated example can be obtained by sandwiching a nonwoven fabric such as a thermal bond with a pair of upper and lower heated molds. As the upper and lower molds, those having a crest and a trough that fit each other are used.

  The sheet pieces 400 illustrated in FIGS. 10 and 11 can be used not only as the skin contact sheet 134 but also interposed between the skin contact sheet 134 and the filter 132 in FIG. When the gap is about the same as the gap between fibers in the filter 132, the filter 132 can be used instead. In any case, the sheet piece 400 is outside the electrodes 218a and 218b in the depth direction R, and the crest 401 and the trough 402 extend so as to cross the electrodes 218a and 218b. 102 can quickly and electrically connect the electrode 218a and the electrode 218b. In the urine receiver 102 illustrated in FIG. 4, when the air-impermeable sheet 124 includes hydrophilic fibers such as rayon fibers in addition to thermoplastic synthetic fibers and has an effect of diffusing urine, the diffusion sheet The use of 126 can be omitted.

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 from which the insulating coating is peeled off. The perspective view of a sheet piece. The figure which shows the XX cut surface of FIG. The figure similar to FIG. 10 which shows an example of a skin contact sheet.

Explanation of symbols

100a Urine suction means 102 Urine receiver 112 Container 112a Opening 112b Bottom 112c Peripheral wall 114 Opening
143 electrodes
144 electrode 134 Liquid-permeable sheet (skin application sheet)
126 Liquid-permeable sheet piece (diffusion sheet)
400 sheet piece 400a outer surface (upper surface)
400b Inner surface (lower surface)
401 Mountain portion 402 Valley portion 407 Thermoplastic synthetic fiber P Longitudinal direction Q Lateral direction R Depth (thickness) direction

Claims (5)

A urine discharge conduit that penetrates the peripheral wall of the leak-proof container having a bottom, a peripheral wall, and a top opening defined by the peripheral wall can be connected to a urine suction means separate from the container. The top opening is covered with a plurality of liquid-permeable sheets that overlap each other, and a pair of electrodes extending in one direction in parallel with each other is provided between the plurality of liquid-permeable sheets. When the pair of electrodes are electrically connected via urine contained in any of the plurality of liquid-permeable sheets, the urine suction means is activated to excrete the wearer of the container. A urine receiver that enables suction from an opening to the container and discharge of the sucked urine from the conduit,
Any one of the plurality of liquid-permeable sheets and located outside the pair of electrodes in the depth direction of the container is formed of a nonwoven fabric containing a thermoplastic synthetic fiber, and the depth An outer surface facing outward in the direction and an inner surface facing inward in the depth direction, and the outer surface is formed with undulations in which peaks and valleys alternately appear in the one direction, And the said urine receiver is in the state which the said peak part and the said trough part extend in the direction which cross | intersects the said one direction, and crosses the said pair of electrodes.   The urine receiver according to claim 1, wherein the sheet on which the undulation is formed on the outer surface is in close contact with the liquid-permeable sheet that has a flat inner surface and faces the inner surface.   2. The sheet on which the undulation is formed on the outer surface, the inner surface is parallel to the outer surface, and the inner surface of the valley portion is in close contact with the liquid-permeable sheet facing the inner surface. The urine receiver described.   The urine receiver according to claim 1, wherein a top portion of the peak portion is hydrophobic and a bottom portion of the valley portion is hydrophilic.   The urine receiver according to any one of claims 1 to 4, wherein the nonwoven fabric includes a plurality of the thermoplastic synthetic fibers extending in a direction intersecting the one direction in the valley portion.

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