JP2021050957A - Water content detection tag and excretion care tool fitted therewith - Google Patents

Abstract

To accurately and easily detect the generation of water content by a simple structure.SOLUTION: The water content detection tag comprises: a substrate 10 having hygroscopic property; an antenna 12 and loop-shaped sensor wiring 13 formed on the substrate 10; an IC chip 11 connected to the antenna 12 and sensor wiring 13, for detecting the electrical continuity state of the sensor wiring 13 and contactlessly transmitting the detection result via the antenna 12; and auxiliary wiring 12a connected at one end to the antenna 12 and extending from the antenna 12 toward the sensor wiring 13. The sensor wiring 13 and the auxiliary wiring 12a include detection areas 12b, 13b that are arranged via a shorting occurrence portion 13a of the substrate 10 where neither of the antenna 12 and the sensor wiring 13 is formed.SELECTED DRAWING: Figure 1

Description

The present invention relates to a technique for detecting the generation of moisture without visual inspection.

In recent years, with the diversification of medical products, diapers have been developed and sold not only for babies but also for the elderly. Since it is preferable that such a diaper be replaced as soon as possible after the wearer has excreted it, a mechanism for notifying that the diaper has been excreted has been considered. As one of them, a mechanism is adopted in which the color changes when the wearer excretes. However, diapers that notify excretion by discoloration are easy to confirm in infants, but in order to confirm discoloration, it is necessary to expose the diaper by taking off clothes etc. Difficult to hire.

Here, in the above-mentioned diaper, there is a technique for detecting a leak by incorporating an IC tag having two wetness detection terminals into the diaper, which makes communication impossible when the wetness detection terminals are short-circuited due to moisture due to leakage. , Patent Document 1. Further, an expansion material that expands by absorbing moisture is provided on the substrate, and wiring is formed over the expansion material, and the expansion material absorbs moisture and expands to break the wiring. Patent Document 2 discloses an IC tag that detects the generation of moisture by detecting a disconnection.

Therefore, by attaching the IC tag as described above to the diaper, it becomes possible to grasp the excretion by the diaper wearer without visually recognizing it.

Japanese Patent No. 4765088 Japanese Unexamined Patent Publication No. 2008-298649

However, in the technique disclosed in Patent Document 1, when the wetness detection terminals are short-circuited due to moisture due to leakage, communication becomes impossible and excretion is detected. Therefore, communication is not possible due to a failure of the IC tag. Even if it becomes possible, there is a problem that it is judged that it has been excreted even though it has not been excreted. Patent Document 1 describes that IC tags having different wavelengths are separately installed as a countermeasure, but the operation becomes complicated and the cost of the IC tag increases. In addition, when the IC tag is installed inside the diaper or inside the diaper, excess water adheres to the IC tag, which changes the communication characteristics and makes it impossible to accurately detect the presence or absence of excretion. There is a risk that it will end up. Further, when the IC tag is installed inside the diaper, there is a problem that the manufacturing process of the diaper becomes complicated.

Further, in the IC tag described in Patent Document 2, since the expansion material is provided on the base material, the cost for that amount is required, and the substrate is uneven due to the expansion material. As a result, there is a problem that the manufacturing process becomes complicated, for example, it becomes difficult to form the wiring.

Further, in the configuration using the IC tag as described in Patent Documents 1 and 2, when water adheres to the IC chip, the IC chip is damaged and the presence or absence of excretion can be accurately detected. There is a risk that it will not be possible.

The above-mentioned problems occur not only in diapers but also in moisture detection sheets for detecting the generation of moisture, such as complicated manufacturing process and erroneous detection of the generation of moisture. Is.

The present invention has been made in view of the problems of the prior art as described above, and is attached to a moisture detection sheet capable of accurately and easily detecting the generation of moisture with a simple configuration. The purpose is to provide excretion care equipment.

In order to achieve the above object, the present invention
A moisture detection tag that is attached to the object to be detected and detects moisture.
A base material with hygroscopicity and
A communication antenna formed on the base material and
The loop-shaped sensor wiring formed on the base material and
A detection means connected to the communication antenna and the sensor wiring, provided on the base base material, detecting the conduction state of the sensor wiring, and non-contact transmitting the detection result via the communication antenna.
One end is connected to the communication antenna and has a short-circuit auxiliary wiring extending in a direction away from the detection means.
The sensor wiring and the short-circuit auxiliary wiring include a detection region arranged via a short-circuit generating portion in which neither the communication antenna of the base material nor the sensor wiring is formed.

In the present invention configured as described above, the sensor wiring of the moisture detection tag is in the first conductive state when moisture is not generated in the adherend to which the moisture detection tag is attached. This is detected by the detection means and transmitted in a non-contact manner via the communication antenna. After that, when moisture is generated in the adherend, the generated moisture short-circuits the communication antenna and the sensor wiring, so that the conduction state of the sensor wiring changes to a second conduction state, and that fact becomes a detection means. Is detected and transmitted in a non-contact manner via a communication antenna. Then, when the sensor wiring of the moisture detection tag is in the first conductive state, it is determined that moisture is not generated in the adherend, and when the sensor wiring is in the second conductive state, the adherend is in the second conductive state. It will be judged that water is being generated. Here, on the base material, one end is connected to the communication antenna, and a short-circuit auxiliary wiring extending in a direction away from the detection means is formed, and the sensor wiring and the short-circuit auxiliary wiring are formed. Since it has a detection area arranged via a short-circuit generating portion in which neither the communication antenna of the base material nor the sensor wiring is formed, the short-circuit generating portion is a place where it is desired to detect the generation of moisture in the adherend. When moisture is generated in the adherend, a short circuit is generated between the detection area of the sensor wiring and the short circuit auxiliary wiring, thereby causing the communication antenna and the communication antenna via the short circuit auxiliary wiring. It can be short-circuited with the sensor wiring. Therefore, a short circuit can occur between the communication antenna and the sensor wiring due to the generation of moisture in a region away from the detection means, and the moisture generated in the adherend is less likely to adhere to the detection means, and the detection means is damaged. Can be avoided.

Further, if the area of the base material provided with the detection means and the communication antenna is covered from the front and back with a pair of protective materials having water shielding properties, excess moisture adheres to the communication antenna and is used for communication. It is possible to prevent the communication characteristics in non-contact communication via the antenna from fluctuating and changing, and while the moisture generated in the adherend can short-circuit the communication antenna and the sensor wiring, the moisture content. It is possible to more reliably avoid damage to the detection means and the communication antenna due to moisture or moisture.

Further, if at least one of the pair of protective materials is composed of an adhesive, the moisture detection tag can be attached to the adherend by using the protective material.

Further, if a pressing paper formed by being pressed in the thickness direction is used as the base material, it becomes easy to form the sensor wiring.

Further, if the sensor wiring is embedded in the base material, the sensor wiring does not protrude from the base material, so that an object such as a worker's hand or a manufacturing device does not get caught in the sensor wiring at the time of manufacturing. It is possible to avoid disconnection of the sensor wiring from time to time.

In addition, when attaching the above-mentioned moisture detection tag to an excretion care device having a diaper body and a diaper cover that covers the diaper body, if the moisture detection tag is sandwiched between the diaper cover and the diaper body and attached, After the wearer of the excretion care device excretes, the moisture detection tag can be taken out from between the diaper cover and the diaper body and reused.

In the present invention, when the sensor wiring of the moisture detection tag is in the first conductive state, it is determined that moisture is not generated in the adherend, and when the sensor wiring is in the second conductive state, it is covered. In the configuration in which it is determined that moisture is generated in the body, one end is connected to the communication antenna and the short-circuit auxiliary wiring extending in the direction away from the detection means is formed on the base material. The short circuit occurs because the sensor wiring and the short circuit auxiliary wiring have a detection region arranged via a short circuit generation portion in which neither the communication antenna of the base material nor the sensor wiring is formed. By facing the part to the part where the generation of moisture in the adherend is to be detected, when moisture is generated in the adherend, a short circuit is generated between the detection area between the sensor wiring and the auxiliary wiring for short circuit, which causes a short circuit. As a result, the communication antenna and the sensor wiring can be short-circuited via the short-circuit auxiliary wiring. As a result, a short circuit can occur between the communication antenna and the sensor wiring due to the generation of moisture in a region away from the detection means, and the moisture generated on the adherend is less likely to adhere to the detection means, so that the detection means can be used. Damage is avoided, and the generation of moisture can be detected accurately and easily with a simple configuration.

Further, in the base material in which the area where the detection means and the communication antenna are provided is covered from the front and back with a pair of protective materials having water impermeability, excessive moisture adheres to the communication antenna. It is possible to prevent the communication characteristics in non-contact communication via the communication antenna from fluctuating and changing, and it is possible to short-circuit the communication antenna and the sensor wiring by the moisture generated in the adherend. It is possible to more reliably prevent the detection means and the communication antenna from being damaged by moisture or moisture.

Further, in the case where at least one of the pair of protective materials is composed of an adhesive, the moisture detection tag can be attached to the adherend by using the protective material.

Further, when a pressing paper formed by being pressed in the thickness direction is used as the base material, it becomes easy to form the sensor wiring.

Further, in the case where the sensor wiring is embedded in the base material, since the sensor wiring does not protrude from the base material, an object such as a worker's hand or a manufacturing device does not get caught in the sensor wiring at the time of manufacturing. , It is possible to avoid disconnection of the sensor wiring at the time of manufacturing.

In addition, when attaching the above-mentioned moisture detection tag to an excretion care device having a diaper body and a diaper cover that covers the diaper body, if the moisture detection tag is sandwiched between the diaper cover and the diaper body and attached, After the wearer of the excretion care device excretes, the moisture detection tag can be taken out from between the diaper cover and the diaper body and reused.

It is a figure which shows one Embodiment of the moisture detection tag of this invention, (a) is a surface view, (b) is a cross-sectional view of AA'shown in (a). It is a figure for demonstrating the process of forming the antenna, the sensor wiring and the auxiliary wiring of the excretion detection tag shown in FIG. It is a figure which shows the usage form of the excretion detection tag shown in FIG. 1, (a) is an external view, (b) is the cross-sectional view of AA'shown in (a), (c) is the detail of the excretion detection tag. It is a figure for demonstrating the mounting position. It is a figure for exemplifying the operation of the excretion detection tag shown in FIG. It is a figure which shows the other embodiment of the moisture detection tag of this invention, (a) is a surface view, (b) is a cross-sectional view of AA'shown in (a), (c) is a base base material. It is a figure which shows the structure of the surface. It is a figure which shows the other embodiment of the moisture detection tag of this invention, (a) is a surface view, (b) is a cross-sectional view of AA'shown in (a), (c) is (a). It is a cross-sectional view of BB'shown. It is a figure which shows the other embodiment of the moisture detection tag of this invention, (a) is a surface view, (b) is a cross-sectional view of AA'shown in (a), (c) is (a). It is a cross-sectional view of BB'shown. It is a figure which shows the other embodiment of the moisture detection tag of this invention, (a) is a surface view, (b) is a cross-sectional view of AA'shown in (a), (c) is (a). It is a cross-sectional view of BB'shown.

Hereinafter, embodiments of the present invention will be described with reference to the drawings.

1A and 1B are views showing an embodiment of the moisture detection tag of the present invention, in which FIG. 1A is a surface view and FIG. 1B is a cross-sectional view taken along the line AA'shown in FIG.

In this embodiment, as shown in FIG. 1, an antenna 12 for non-contact communication, a sensor wiring 13 and an auxiliary wiring 12a for short circuit are formed on one surface of the base base material 10, and an IC chip 11 is mounted. It is an excretion detection tag 1 configured in the above.

The base base material 10 is formed by applying a protective coating film such as a resin that allows moisture to permeate on the surface of a base material having hygroscopicity such as a fiber material or a non-woven fabric, for example, coated paper or the like is thick. It is composed of pressed paper formed by being pressed in the longitudinal direction. For example, a SWORD mat made by Mitsubishi Paper Mills can be used. As the base base material 10, a base material itself having hygroscopicity such as a fiber material or a non-woven fabric may be used.

The antenna 12, the sensor wiring 13, and the auxiliary wiring 12a are formed by being embedded in one surface of the base base material 10 by a manufacturing process described later. The antenna 12 is composed of two conductive regions in which feeding points connected to the IC chip 11 face each other through a gap. One end of the sensor wiring 13 is connected to the IC chip 11, extends from the sensor wiring 13 in a direction away from the IC chip 11 and folded back, and the other end is connected to the IC chip 11 in a loop shape. One end of the auxiliary wiring 12a is connected to an end opposite to one of the feeding points of the two conductive regions constituting the antenna 12, and the folded portion of the sensor wiring 13 is separated from the IC chip 11 from the end. The other end of the sensor wiring 13 extends linearly toward the direction of the sensor wiring 13 and is terminated in a region adjacent to the folded portion of the sensor wiring 13. Each of the auxiliary wiring 12a and the sensor wiring 13 has detection regions 12b and 13b arranged via a short-circuit generating portion 13a in which neither the sensor wiring 13 of the base base material 10 nor the antenna 12 is formed. ing.

The IC chip 11 is a detection means in the present invention. The IC chip 11 is provided with two antenna terminals (not shown) and two moisture detection terminals (not shown), and the surface provided with these antenna terminals and the moisture detection terminal serves as a mounting surface. The antenna 12, the sensor wiring 13, and the auxiliary wiring 12a of the base base material 10 are mounted on the formed surface. Each of the antenna terminals of the IC chip 11 is connected to the antenna 12, and the moisture detection terminals of the IC chip 11 are connected to both ends of the loop-shaped sensor wiring 13. The IC chip 11 detects the continuity state of the sensor wiring 13 and is configured to be able to communicate with an external device via the antenna 12, and transmits the detection result in a non-contact manner via the antenna 12. It is conceivable that the conduction state of the sensor wiring 13 is detected by detecting the resistance value of the sensor wiring 13 by passing a current through the sensor wiring 13 by the electromotive force acquired through the antenna 12, for example. As the IC chip 11, for example, UCODE G2iM + and UCODE G2iL + manufactured by NXP semiconductors can be considered.

Hereinafter, a method for manufacturing the excretion detection tag 1 configured as described above will be described.

When manufacturing the excretion detection tag 1 shown in FIG. 1, first, the antenna 12, the sensor wiring 13, and the auxiliary wiring 12a are formed on one surface of the base base material 10.

FIG. 2 is a diagram for explaining a process of forming the antenna 12, the sensor wiring 13, and the auxiliary wiring 12a of the excretion detection tag 1 shown in FIG. 1, and shows a cross-sectional view in the vicinity of the sensor wiring 13.

When forming the antenna 12, the sensor wiring 13, and the auxiliary wiring 12a of the excretion detection tag 1 shown in FIG. 1, first, as a printing step, as shown in FIG. 2A, the conductive particles 31 made of copper or the like are formed. However, the conductive ink 30 contained in the binder 32 composed of the resin and the solvent is applied onto the base base material 10 in the shape of the antenna 12, the sensor wiring 13 and the auxiliary wiring 12a by screen printing. At this time, the base base material 10 is made of coated paper or the like coated with a protective coating film, and is formed by being pressed in the thickness direction, so that the conductive ink 30 is a base base. It becomes difficult to penetrate the material 10, and the antenna 12, the sensor wiring 13, and the auxiliary wiring 12a are easily formed.

Next, as a drying step, the coating film with the conductive ink 30 is dried. By performing this drying step, the adhesion between the base base material 10 and the antenna 12, the sensor wiring 13, and the auxiliary wiring 12a becomes better. The drying step is preferably performed in a time of 10 minutes or less.

Next, as a pressing step, as shown in FIG. 2B, for example, the base base material 10 is sandwiched between two rolls and linearly pressed to pressurize the base base material 10 from the front and back. The method of pressurizing the base base material 10 is not limited to the one using two rolls, and the base base material 10 may be sandwiched between flat plates and surface-pressurized. When the base base material 10 is pressed from the front and back by the pressing process, the conductive particles 31 existing inside the coating film by the conductive ink 30 are densified, whereby, for example, the conductivity of 10 μΩ · cm or less is good. The antenna 12, the sensor wiring 13, and the auxiliary wiring 12a can be obtained.

Further, when the base base material 10 is pressed from the front and back, the base base material 10 is made of a soft material such as coated paper, and as shown in FIG. 2C, the antenna 12, the sensor wiring 13, and the auxiliary are provided. The wiring 12a is embedded in the base base material 10, whereby the antenna 12, the sensor wiring 13, and the auxiliary wiring 12a are embedded in the base base material 10 with only the surface exposed.

Next, the IC chip 11 is mounted on the base base material 10 so as to be connected to the antenna 12 and the sensor wiring 13.

At this time, since the antenna 12, the sensor wiring 13 and the auxiliary wiring 12a are embedded in the base base material 10, the antenna 12, the sensor wiring 13 and the auxiliary wiring 12a do not protrude from the base base material 10. As a result, in the process of mounting the IC chip 11 on the base base material 10 and the subsequent processing process of the excretion detection tag 1, an object such as a worker's hand or a manufacturing device can be removed from the antenna 12, the sensor wiring 13, and the auxiliary wiring. It is possible to prevent the antenna 12, the sensor wiring 13, and the auxiliary wiring 12a from being disconnected at the time of manufacturing by eliminating the possibility of being caught in the 12a.

The operation of the excretion detection tag 1 described above will be described below.

First, the usage pattern of the excretion detection tag 1 shown in FIG. 1 will be described.

3A and 3B are views showing a usage pattern of the excretion detection tag 1 shown in FIG. 1, in which FIG. 3A is an external view, FIG. 3B is a cross-sectional view taken along the line AA'shown in FIG. It is a figure for demonstrating the detailed attachment position of the excretion detection tag 1. FIG.

As shown in FIG. 3, the excretion detection tag 1 shown in FIG. 1 is attached between the diaper body 40 to be detected and the diaper cover 50, and is used as a diaper 2 as an excretion care tool.

The diaper body 40 is configured such that a water absorbing body 43 is sandwiched between a first body-side sheet 41 having water permeability and a first anti-body-side sheet 42 having water-shielding and moisture-permeable properties. In the diaper cover 50, the water absorbent 53 is sandwiched between the second body-side sheet 51 having water permeability and the second anti-body-side sheet 52 having water-shielding and moisture-permeable properties. It is composed of. For the purpose of preventing stuffiness, the antibody side sheets 42 and 52 are formed by melt-kneading an inorganic filler in an olefin resin such as polyethylene or polypropylene to form a sheet, and then stretching in the uniaxial or biaxial direction. It is composed of the microporous sheet obtained by the above method, and can be provided with moisture permeability without impairing the water-shielding property.

The excretion detection tag 1 is a diaper cover with an adhesive tape or the like so that the surface of the base base material 10 on which the antenna 12 and the sensor wiring 13 are not formed faces the diaper cover 50 between the diaper body 40 and the diaper cover 50. It is attached and fixed to the body side sheet 51 of 50. As a result, the excretion detection tag 1 is sandwiched between the body-side sheet 51 of the diaper cover 50 and the anti-body-side sheet 42 of the diaper body 40 on the surface of the body-side sheet 51 of the diaper cover 50 facing the diaper body 40. It will be installed in a diaper state. Further, as shown in FIG. 3C, the excretion detection tag 1 generates moisture due to excretion in the short-circuit generating portion 13a, in the portion B in the figure including the region where the auxiliary wiring 12a and the sensor wiring 13 are closest to each other. It is attached so as to face the part to be used. In the present embodiment, the auxiliary wiring 12a is connected to the end of the two conductive regions opposite to the feeding point of one of the two conductive regions, and the auxiliary wiring 12a is separated from the IC chip 11 from the end of the auxiliary wiring 12a. Since the auxiliary wiring 12a and the sensor wiring 13 are close to each other because they extend linearly toward the folded portion of the sensor wiring 13 and the other end is terminated in a region adjacent to the folded portion of the sensor wiring 13. Part B in the drawing including the region to be formed is attached so as to face the portion where water is generated due to excretion. As a result, when water is generated by excretion, the auxiliary wiring 12a and the sensor wiring 13 are likely to be short-circuited at the short-circuit generating portion 13a as described later, and the generation of water can be detected at an early stage. .. As described above, the other end of the auxiliary wiring 12a, which is not connected to the antenna 12, faces the folded-back portion of the sensor wiring 13 via the short-circuit generating portion 13a. This means a state in which the end surface of the other end of the wiring 12a faces the sensor wiring 13.

In this way, the user wears the diaper 2 to which the excretion detection tag 1 is attached between the diaper body 40 and the diaper cover 50. As a result, the diaper cover 50 to which the excretion detection tag 1 is attached and fixed to the body side sheet 51 is attached so as to cover the diaper main body 40.

Next, the operation when the excretion detection tag 1 shown in FIG. 1 is attached between the diaper main body 40 and the diaper cover 50 as shown in FIG. 3 will be described.

FIG. 4 is a diagram for schematically explaining the operation of the excretion detection tag 1 shown in FIG.

The sensor wiring 13 of the excretion detection tag 1 shown in FIG. 1 has a loop shape in which both ends are connected to the two moisture detection terminals of the IC chip 11, so that the excretion detection is detected as shown in FIG. If the user is wearing the diaper 2 with the tag 1 attached between the diaper body 40 and the diaper cover 50 and the user of the diaper 2 is not excreting, as shown in FIG. 4 (a). The sensor wiring 13 is in a first conductive state in which it is not electrically connected to the antenna 12.

Therefore, when power is supplied to the excretion detection tag 1 in a non-contact state from an external device attached to the bed on which the user is sleeping or an external device such as a smartphone, a current flows through the sensor wiring 13, which causes a current to flow. In the IC chip 11, the resistance value of the sensor wiring 13 is detected as being smaller than a predetermined value (almost the resistance value set in the sensor wiring 13).

In that case, in the IC chip 11, for example, "1" is set as the flag information, and this flag information is non-contact transmitted to the external device via the antenna 12 as the detection result of the continuity state of the sensor wiring 13.

Then, when the received flag information is "1" in the external device, it is determined that the user of the diaper 2 has not excreted.

On the other hand, when the user of the diaper 2 shown in FIG. 3 excretes, the body-side sheet 41 of the diaper body 40 has water permeability, so that urine permeates the body-side sheet 41 and absorbs water. Water is absorbed by the body 43. Further, since the anti-body side sheet 42 has water impermeability and moisture permeability, the moisture from the urine absorbed by the water-absorbing body 43 permeates the anti-body side sheet 42 and is on the anti-body side. It will adhere to the excretion detection tag 1 attached to the outside of the sheet 42.

The excretion detection tag 1 is configured such that the base base material 10 is coated with a protective coating film such as a resin that allows moisture to permeate on the surface of a base material having hygroscopicity such as a fiber material or a non-woven fabric. Therefore, the attached water is absorbed by the base base material 10.

Then, in the portion of the excretion detection tag 1 in which water is absorbed (part B in FIG. 3C), the auxiliary wiring 12a and the sensor wiring 13 are connected to the base base material 10 between the detection regions 12b and 13b. Neither the sensor wiring 13 nor the antenna 12 of the above is formed so as to be arranged via a short-circuit generating portion 13a, and the end portion of the auxiliary wiring 12a opposite to the end connected to the antenna 12 is formed. Since it is terminated in the region of the sensor wiring 13 that is close to the folded portion, as shown in FIG. 4B, the base is in the region of the short circuit occurrence portion 13a where the auxiliary wiring 12a and the sensor wiring 13 are close to each other. The moisture 13c absorbed by the base material 10 causes a short circuit 13d between the auxiliary wiring 12a and the sensor wiring 13. Since the auxiliary wiring 12a is connected to the antenna 12, the conduction state of the sensor wiring 13 changes to a second conduction state in which the antenna 12 and the sensor wiring 13 are electrically connected, and the IC chip 11 The resistance value of the sensor wiring 13 detected in the above is larger than the predetermined value. At this time, since the antenna 12, the sensor wiring 13, and the auxiliary wiring 12a are embedded in the base base material 10 as described above, when the water content 13c is absorbed by the base base material 10, the water content is the water content. Due to 13c, a short circuit 13d is likely to occur at the short circuit generation portion 13a. Further, the distance between the end of the auxiliary wiring 12a opposite to the end connected to the antenna 12 and the folded-back portion of the sensor wiring 13 can be, for example, in the range of 1 mm to 50 mm, but the length thereof is changed. As a result, the humidity at which the short circuit 13d occurs can be adjusted at the short circuit generating portion 13a.

In this state, when power is supplied to the excretion detection tag 1 in a non-contact state from an external device attached to the bed on which the user is sleeping or an external device such as a smartphone, a current flows through the sensor wiring 13 and the power is supplied. Therefore, in the IC chip 11, the resistance value of the sensor wiring 13 is detected as being larger than the predetermined value. Then, in the IC chip 11, for example, "0" is set as the flag information, and this flag information is non-contact transmitted to the external device via the antenna 12 as the detection result of the continuity state of the sensor wiring 13.

In the external device, when the received flag information is "0", it is determined that the user of the diaper 2 has excreted.

At that time, one end of the base base material 10 is connected to the antenna 12 and extends in a direction away from the IC chip 11, and the other end is either the antenna 12 of the base base material 10 or the sensor wiring 13. Since the auxiliary wiring 12a facing the sensor wiring 13 is formed via the short-circuit generating portion 13a in which the thigh is not formed, the short-circuit generating portion 13a generates water as shown in FIG. 3 (c). By facing the location to be detected, the antenna 12 and the sensor wiring 13 can be short-circuited at the short-circuit generating portion 13a via the auxiliary wiring 12a when moisture is generated. As a result, a short circuit can be caused between the antenna 12 and the sensor wiring 13 due to the generation of moisture in a region away from the IC chip 11, and the generated moisture is less likely to adhere to the IC chip 11, and the IC chip 11 is damaged. This can be avoided, and the generation of moisture can be detected accurately and easily with a simple configuration.

As described above, in the present embodiment, in the excretion detection tag 1 provided on the outside of the antibody side sheet 42 of the diaper body 40 constituting the diaper 2, the conduction state of the sensor wiring 13 changes due to the moisture due to excretion. Since the detection result of the conduction state is transmitted in a non-contact manner via the antenna 12, the configuration is simple without separately providing a moisture-sensitive film on the base material, and the user of the diaper 2 feels uncomfortable. Excretion can be reliably detected without making it feel. Moreover, it will not be confused with the failure of the excretion detection tag 1.

Here, by utilizing the fact that the two conductive regions that are not electrically connected to each other are brought into a conductive state due to the generation of moisture as described above, a disconnection portion is provided in the sensor wiring 13 to generate moisture. In the absence state, it is detected by using the resistance value of the sensor wiring 13 that the sensor wiring 13 is in a disconnected state, and in a state where moisture is generated, the disconnected portion is short-circuited and the sensor wiring 13 becomes a conductive state. A mechanism is conceivable in which this is detected by using the resistance value of the sensor wiring 13 and the generation of moisture is detected by using the change in the conduction state. In such a configuration, when moisture is generated, the disconnection portion is short-circuited and the sensor wiring 13 becomes conductive. However, when the generated moisture is excessive, the sensor wiring 13 is connected to the antenna 12 as described above. As a result, the resistance value of the sensor wiring 13 becomes large, and it may be determined that the sensor wiring 13 is in a disconnected state, that is, a state in which moisture is not generated.

However, in the case of the present embodiment in which the generation of water is detected by utilizing the fact that the antenna 12 and the sensor wiring 13 are short-circuited and electrically connected when water is generated, the water is generated. After that, as long as moisture is generated, the state in which the antenna 12 and the sensor wiring 13 are electrically connected is maintained, and the resistance value of the sensor wiring 13 detected by the IC chip 11 is the antenna 12 and the sensor. It does not return to the value in the state where the wiring 13 is not electrically connected. Therefore, even if the generated water content becomes excessive, the state in which the sensor wiring 13 is electrically connected to the antenna 12 is maintained as described above, and it is determined that the water content is not generated. You can avoid it.

In the diaper 2 used as described above, only the diaper body 40 is discarded after the user excretes, but in the excretion detection tag 1, the diaper 2 is sandwiched between the diaper body 40 and the diaper cover 50. Therefore, the surface of the base base material 10 on which the antenna 12 and the sensor wiring 13 are not formed is attached and fixed to the body side sheet 51 of the diaper cover 50 with an adhesive tape or the like so as to face the diaper cover 50. Even after the user of the diaper 2 excretes, the excretion detection tag 1 can be reused together with the diaper cover 50 if the excretion detection tag 1 is dried to remove the water adhering to the base base material 10. Even if the excretion detection tag 1 is not attached to and fixed to the body side sheet 51 of the diaper cover 50, it is sandwiched between the diaper body 40 and the diaper cover 50, so that the user of the diaper 2 After excretion, the excretion detection tag 1 can be taken out from between the diaper cover 50 and the diaper body 40 and reused. However, if the excretion detection tag 1 is attached and fixed to the body side sheet 51 of the diaper cover 50, the excretion detection tag 1 will be attached and fixed to the diaper cover 50 and reused. Therefore, the excretion detection tag 1 can be sandwiched between the diaper body 40 and the diaper cover 50 simply by covering the diaper body 40 with the diaper cover 50 to be reused.

(Other embodiments)
5A and 5B are views showing another embodiment of the moisture detection tag of the present invention, in which FIG. 5A is a surface view, FIG. 5B is a sectional view taken along the line AA'shown in FIG. It is a figure which shows the composition of the surface of the base base material 10.

In this embodiment, as shown in FIG. 5, a pair of protective base materials 120a and 120b are laminated on the front and back sides of the base base material 10 except for a part of the base material 10 as shown in FIG. It is a different excretion detection tag 101.

The protective base materials 120a and 120b serve as protective materials in the present invention, and the region of the base base material 10 provided with the antenna 12 and the IC chip 11 has a shape slightly larger than that of the base base material 10. In addition to covering from the front and back, the end face of the base base material 10 is also covered in that region. Of the short-circuit generating portion 13a of the base base material 10, the region where the end portion of the auxiliary wiring 12a opposite to the end portion connected to the antenna 12 and the folded portion of the sensor wiring 13 are close to each other is the protective base material 120a, It is exposed without being covered by 120b. The protective base materials 120a and 120b are made of a water-impervious material such as YUPOTAC paper (manufactured by YUPO Corporation), and it is considered that the protective base materials 120a and 120b are attached to the base base material 10 by an adhesive (not shown). Of the protective base materials 120a and 120b, if the protective base material 120b laminated on the surface of the base base material 10 on which the antenna 12 and the sensor wiring 13 are not formed is composed of an adhesive having a water-shielding property, it is excreted. When the detection tag 101 is attached to the diaper cover 50 as described above, the excretion detection tag 101 can be attached to the diaper cover 50 by using the adhesive force of the protective base material 120b. Further, the protective base material 120a may also be composed of an adhesive. As the protective base materials 120a and 120b, a material having a characteristic of not allowing moisture to permeate may be applied onto the base base material 10 or a water vapor barrier film may be laminated.

In the excretion detection tag 101 configured as described above, although the base base material 10 is covered with a pair of protective base materials 120a and 120b having water impermeability, the short-circuit generation portion 13a of the base base material 10 Of these, the region where the end of the auxiliary wiring 12a opposite to the end connected to the antenna 12 and the folded-back portion of the sensor wiring 13 are in close contact with each other is exposed without being covered by the protecting base materials 120a and 120b. Therefore, as shown in FIG. 3, when water is generated due to excretion while being attached between the diaper cover 50 and the diaper body 40, the antenna 12 and the sensor wiring 13 are connected via the auxiliary wiring 12a. A short circuit can be obtained at the short circuit generating portion 13a to obtain the same effect as described above.

Further, in the present embodiment, the area where the antenna 12 and the IC chip 11 of the base base material 10 are provided is covered from the front and back by the protective base materials 120a and 120b, so that the antenna 12 and the IC chip 11 of the base base material 10 are covered. In the area provided with, when moisture adheres to the excretion detection tag 101, it is difficult for the moisture to permeate, and excess moisture adheres to the antenna 12, and the communication characteristics in non-contact communication via the antenna 12 vary and change. It is possible to prevent the antenna 12 and the antenna wiring 13 from being short-circuited by the generated moisture, and it is possible to more reliably prevent the IC chip 11 and the antenna 12 from being damaged by the moisture and moisture.

6A and 6B are views showing another embodiment of the moisture detection tag of the present invention, in which FIG. 6A is a surface view, FIG. 6B is a sectional view taken along the line AA'shown in FIG. It is a cross-sectional view of BB'shown in (a).

As shown in FIG. 6, this embodiment is an excretion detection tag 201 in which the shapes of the sensor wiring 213 and the auxiliary wiring 212a are different from those shown in FIG.

In the excretion detection tag 201 of this embodiment, the other end portion of the auxiliary wiring 212a that is not connected to the antenna 12 faces the sensor wiring 213 in the sense that its end face does not face the sensor wiring 213. The other end, which is not connected to the antenna 12 of the auxiliary wiring 212a, is arranged close to the folded portion of the sensor wiring 213. Therefore, in the excretion detection tag 201 of the present embodiment, when excretion is detected by short-circuiting the antenna 12 and the sensor wiring 213 via the auxiliary wiring 212a, the auxiliary wiring of the short-circuit generating portion 213a of the base base material 10 By short-circuiting the other end of the 212a that is not connected to the antenna 12 and the folded-back portion of the sensor wiring 213, the antenna 12 and the sensor wiring 213 are short-circuited via the auxiliary wiring 212a.

Even in the excretion detection tag 201 configured as described above, when water is generated due to excretion while being attached between the diaper cover 50 and the diaper body 40 as shown in FIG. 3, the antenna 212 and the sensor The wiring 213 is short-circuited at the short-circuit generating portion 213a away from the IC chip 11 via the auxiliary wiring 212a, and the same effect as described above can be obtained.

7A and 7B are views showing another embodiment of the moisture detection tag of the present invention, in which FIG. 7A is a surface view, FIG. 7B is a sectional view taken along the line AA'shown in FIG. It is a cross-sectional view of BB'shown in (a).

As shown in FIG. 7, this embodiment is an excretion detection tag 301 in which the shapes of the sensor wiring 313 and the auxiliary wiring 312a are different from those shown in FIG.

In the excretion detection tag 301 of this embodiment, the auxiliary wiring 312a extends from one end connected to the antenna 12 in parallel with the sensor wiring 313 in a direction away from the IC chip 11, and is not connected to the antenna 12. The end of the antenna is bent so as to face the side opposite to the sensor wiring 313. Even in the excretion detection tag 301 configured in this way, when water is generated by excretion and absorbed by the base base material 10, the antenna 12 and the sensor wiring 313 are short-circuited via the auxiliary wiring 312a, so that excretion occurs. It will be detected. In that case, since the auxiliary wiring 312a and the sensor wiring 313 are in parallel, the amount of water absorbed by the base base material 10 at that time regardless of which region between the auxiliary wiring 312a and the sensor wiring 313 is short-circuited. There is no difference in. Therefore, in the excretion detection tag 301 of the present embodiment, in the region where neither the sensor wiring 313 nor the antenna 312 of the base base material 10 is formed, the auxiliary wiring 312a and the sensor wiring 313 extend in parallel with each other. All of the regions are short-circuit generation portions 313a, and the regions arranged via the short-circuit generation portion 313a of the auxiliary wiring 312a and the sensor wiring 313 are the detection regions 312b and 313b, respectively, in any region of the short-circuit generation portion 313a. By short-circuiting the detection areas 312b and 313b, it is possible to detect the generation of water due to excretion.

Even in the excretion detection tag 301 configured as described above, when water is generated due to excretion while being attached between the diaper cover 50 and the diaper body 40 as shown in FIG. 3, the antenna 312 and the sensor The wiring 313 can be short-circuited via the auxiliary wiring 312a in a region of the short-circuit generating portion 313a that is separated from the IC chip 11, and the same effect as described above can be obtained.

8A and 8B are views showing another embodiment of the moisture detection tag of the present invention, in which FIG. 8A is a surface view, FIG. 8B is a sectional view taken along the line AA'shown in FIG. It is a cross-sectional view of BB'shown in (a).

As shown in FIG. 8, this embodiment is an excretion detection tag 401 in which the shapes of the sensor wiring 413 and the auxiliary wiring 412a are different from those shown in FIG.

In the excretion detection tag 401 of this embodiment, the auxiliary wiring 412a gradually moves away from the sensor wiring 413 in the direction away from the IC chip 11 from one end connected to the antenna 12. It is formed so as to move away from it. Even in the excretion detection tag 401 configured in this way, when water is generated by excretion and absorbed by the base base material 10, the antenna 12 and the sensor wiring 413 are short-circuited via the auxiliary wiring 412a, so that excretion occurs. It will be detected. In that case, since the auxiliary wiring 412a and the sensor wiring 413 are formed so as to gradually separate from the IC chip 11, the amount of water generated when the user determines that the wiring has been excreted, That is, the auxiliary wiring 412a and the sensor wiring 413 can be short-circuited at an arbitrary position according to the sensitivity. Therefore, in the excretion detection tag 401 of the present embodiment, the auxiliary wiring 412a and the sensor wiring 413 gradually separate from each other in the region where neither the sensor wiring 413 nor the antenna 412 of the base base material 10 is formed. All of the regions are short-circuit generation portions 413a, and the regions arranged via the short-circuit generation portions 413a of the auxiliary wiring 412a and the sensor wiring 413 are the detection regions 412b and 413b, respectively, and any region of the short-circuit generation portion 413a. By short-circuiting the detection areas 412b and 413b at the above, it is possible to detect the generation of water due to excretion.

Even in the excretion detection tag 401 configured as described above, when water is generated due to excretion while being attached between the diaper cover 50 and the diaper body 40 as shown in FIG. 3, the antenna 412 and the sensor The wiring 413 can be short-circuited via the auxiliary wiring 412a in a region of the short-circuit generating portion 413a that is separated from the IC chip 11, and the same effect as described above can be obtained.

Further, in the present embodiment, since the auxiliary wiring 412a is formed so as to gradually move away from the sensor wiring 413 as the distance from the IC chip 11 increases, the auxiliary wiring 412a and the sensor wiring 413 in the short-circuit generating portion 413a The intervals are not constant. Therefore, the amount of water, that is, the sensitivity at the time of detecting that the antenna 12 and the sensor wiring 413 are short-circuited via the auxiliary wiring 412a due to the short circuit occurring in the short-circuit generating portion 413a and water is generated is arbitrarily set. be able to. For example, when it is desired to detect that moisture is generated only by generating a small amount of moisture, the portion of the short-circuit generating portion 413a where the distance between the auxiliary wiring 412a and the sensor wiring 413 is narrow is desired to be detected. It is possible to detect that a short circuit has occurred between the detection area 412b of the auxiliary wiring 412a and the detection area 413b of the sensor wiring 413 to generate water even if a small amount of water is generated. On the contrary, if it is desired to prevent the generation of moisture from being detected unless a large amount of moisture is generated, the region of the short-circuit generating portion 413a where the distance between the auxiliary wiring 412a and the sensor wiring 413 is wide is moisture. If a large amount of water is not generated by facing the location where the occurrence of is desired to be detected, the fact that water is generated without causing a short circuit between the detection area 412b of the auxiliary wiring 412a and the detection area 413b of the sensor wiring 413. Will not be detected.

In the above-described embodiment, the auxiliary wirings 12a, 212a, 312a, and 412a extend linearly in the direction away from the IC chip 11, but reciprocate in the direction away from the IC chip 11 and the direction closer to the IC chip 11. It may be formed so as to extend in a direction away from the IC chip 11 while reciprocating in a direction substantially orthogonal to the direction away from the IC chip 11.

Further, if the shape of the auxiliary wiring extends in the direction away from the IC chip 11 as a whole, the shape of the end portion on the opposite side of the IC chip 11 is a T-shape, an arrow, or a triangular shape. Or, it may be a part of the IC chip 11 facing the IC chip 11 by being swirled.

Further, the excretion detection tags 1, 101, 201, 301, 401 described above are not limited to the diaper 2 as described above, and can also be used as a moisture detection tag for detecting water leakage or the like at a joint portion of a building member or the like.

1,101,201,301,401 Excretion detection tag 2 Diaper 10 Base base material 11 IC chip 12 Antenna 12a, 212a, 312a, 412a Auxiliary wiring 12b, 13b, 212b, 213b, 312b, 313b, 412b, 413b Detection area 13 , 213,313,413 Sensor wiring 13a, 213a, 313a, 413a Short-circuit generating part 13c Moisture 13d Short-circuit 30 Conductive ink 31 Conductive particles 32 Binder 40 Diaper body 41,51 Body side sheet 42,52 Anti-body side sheet 43, 53 Water absorber 50 Diaper cover 120a, 120b Protective base material

Claims (6)

A moisture detection tag that is attached to the object to be detected and detects moisture.
A base material with hygroscopicity and
A communication antenna formed on the base material and
The loop-shaped sensor wiring formed on the base material and
A detection means connected to the communication antenna and the sensor wiring, provided on the base base material, detecting the conduction state of the sensor wiring, and non-contact transmitting the detection result via the communication antenna.
One end is connected to the communication antenna and has a short-circuit auxiliary wiring extending in a direction away from the detection means.
The sensor wiring and the short-circuit auxiliary wiring include a moisture detection tag having a detection region arranged via a short-circuit generating portion in which neither the communication antenna of the base material nor the sensor wiring is formed. .. In the moisture detection tag according to claim 1,
The base material is a moisture detection tag in which a region provided with the detection means and the communication antenna is covered from the front and back with a pair of protective materials having water shielding properties. In the moisture detection tag according to claim 2,
A moisture detection tag in which at least one of the pair of protective materials is composed of an adhesive. In the moisture detection tag according to any one of claims 1 to 3, the moisture detection tag
The base material is a moisture detection tag which is a pressing paper formed by being pressed in the thickness direction. In the moisture detection tag according to any one of claims 1 to 4, the moisture detection tag
The sensor wiring is a moisture detection tag embedded in the base material. An excretion care device to which the moisture detection tag according to any one of claims 1 to 5 is attached.
Between the first body-side sheet having moisture permeability, the first anti-body-side sheet having water-shielding and moisture-permeable, and the first body-side sheet and the first anti-body-side sheet. The diaper body, which consists of a water absorber sandwiched between
Between the second body-side sheet having moisture permeability, the second anti-body-side sheet having water-shielding and moisture-permeable, and the second body-side sheet and the second anti-body-side sheet. It consists of a water absorbent sandwiched between the diapers and has a diaper cover that covers the diaper body.
An excretion care device in which the moisture detection tag is sandwiched between the first anti-body side sheet and the second body side sheet.

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