JP2013195364A - Liquid detection sensor - Google Patents

Abstract

Water leakage is reliably detected by preventing displacement.
A liquid sensing sheet for sensing a liquid and an adhesive member having adhesiveness that can be attached to an installation target are provided. The liquid sensing sheet 1 has a configuration in which an insulating sheet 4 that exhibits conductivity by the presence of liquid is disposed between the conductive sheets 3 and 5. The conductive sheets 3 and 5 have through portions 31 and 51 through which at least one of the liquids passes.
[Selection] Figure 1

Description

  The present invention relates to a liquid detection sensor for detecting a liquid such as water or oil.

  Conventionally, as a sensor for detecting water leakage, a pair of metal net-like sheets and electrode tapes are connected by a water-permeable insulating sheet, and the peripheral part of the laminate of these sheets is integrated by bonding with an adhesive. Proposed. And, in use, a sensor is placed or wound around the leak detection part, and the leak is detected by measuring the electrical resistance value between the metal mesh sheet and the electrode tape. (Patent Documents 1 and 2).

JP 2007-143895 A JP-A-4-21852

  By the way, in the configuration in which the sensor is placed or wound around the detection site as in the conventional case, when the detection target vibrates or moves, the sensor is likely to be displaced from the initial installation position. It is difficult to reliably detect water leakage.

  The present invention has been made in view of the above problems, and an object of the present invention is to provide a liquid sensing sheet that can reliably detect water leakage by preventing misalignment.

  The present invention is a liquid detection sensor having the following configuration, a liquid detection sheet in which an insulating sheet that exhibits conductivity by the presence of liquid is disposed between the conductive sheets, and the liquid detection sheet is provided with an adhesive property. And having an adhesive member.

  According to the above configuration, the liquid sensing sheet can be fixed to the installation target by adhering the adhesive member to the installation target. Thereby, even when the installation target vibrates or moves, the positional relationship between the installation target and the liquid detection sensor can be maintained. As a result, as compared with the conventional case where the liquid detection sensor is merely placed, positional displacement is unlikely to occur, and thus it is possible to reliably detect liquid leakage.

  The present invention further includes a liquid-permeable sheet that covers one surface of the liquid sensing sheet, and the conductive sheet has a penetrating portion that allows at least one of the liquid to pass therethrough, and the adhesive member includes In addition, an adhesive material for fixing the liquid-permeable sheet may be provided.

  According to said structure, when a liquid detection sensor is fixed by the adhesion member, the penetration part of an electroconductive sheet is not obstruct | occluded.

  The present invention may include a liquid permeable sheet that covers the other surface of the liquid sensing sheet. According to this configuration, both surfaces of the liquid sensing sheet can be protected by the liquid permeable sheet.

  The present invention further comprises a liquid-permeable sheet that covers the periphery of the liquid sensing sheet, and the conductive sheet has a penetrating portion that allows at least one of the liquid to pass therethrough, The adhesive member may include an adhesive material that fixes the liquid-permeable sheet.

  According to said structure, since the circumference | surroundings of a liquid sensing sheet can be covered with one liquid-permeable sheet, the process which covers the one surface and the other surface of the liquid sensing sheet 1 with a liquid-permeable sheet is performed by 1 process. Can do.

  The pressure-sensitive adhesive member in the present invention may have a release sheet that covers the pressure-sensitive adhesive material. According to said structure, while being able to hold | maintain the adhesiveness of an adhesive material for a long term, it becomes the thing excellent in portability.

  The present invention may have a terminal portion formed by exposing a part of the conductive sheet. According to said structure, it can prepare for detecting a liquid leak easily by connecting a measuring device to a terminal part.

  In the present invention, the terminal portion in one of the conductive sheets and the terminal portion in the other conductive sheet may be arranged so as not to overlap each other in the thickness direction. According to said structure, the operation | work which connects a measuring device to a terminal part can be performed still more easily.

  The present invention includes a liquid-permeable insulating sheet that exhibits electrical conductivity through the presence of a liquid, and a conductive sheet bonded to both surfaces of the insulating sheet, and at least one of the conductive sheets includes the liquid The insulating sheet and the conductive sheet are provided on the liquid sensing sheet, the liquid sensing sheet joined by an adhesive dispersedly disposed on the whole joining surface, and the adhesive sheet. A pressure-sensitive adhesive member.

  According to the above configuration, the liquid sensing sheet can be fixed to the installation target by adhering the adhesive member to the installation target. Thereby, even when the installation target vibrates or moves, the positional relationship between the installation target and the liquid detection sensor can be maintained. As a result, as compared with the conventional case where the liquid detection sensor is merely placed, positional displacement is unlikely to occur, and thus it is possible to reliably detect liquid leakage.

  It is possible to reliably detect water leakage by preventing misalignment.

It is explanatory drawing of a liquid detection sensor. It is explanatory drawing which shows the cross-section of a liquid detection sensor. It is a disassembled perspective view of a liquid detection sensor. It is explanatory drawing which shows the usage condition of a liquid detection sensor. It is explanatory drawing of a liquid detection sensor. It is explanatory drawing of a liquid detection sensor. It is explanatory drawing of a liquid detection sensor. It is explanatory drawing of a liquid detection sensor. It is explanatory drawing of a liquid sensing sheet. It is explanatory drawing which showed the relationship of arrangement | positioning of a penetration part and an adhesive agent. It is explanatory drawing which showed the relationship of arrangement | positioning of a penetration part and an adhesive agent. It is explanatory drawing which showed the relationship of arrangement | positioning of a penetration part and an adhesive agent. It is explanatory drawing which showed the relationship of arrangement | positioning of a penetration part and an adhesive agent. It is principal part sectional drawing of a liquid sensing sheet. It is explanatory drawing of a liquid sensing sheet.

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

(Liquid detection sensor: overall configuration)
As shown in FIG. 1, a liquid detection sensor 201 according to the present embodiment includes a liquid detection sheet 1 that detects a liquid, and an adhesive member 202 having adhesiveness that can be attached to an installation target. The liquid sensing sheet 1 has a configuration in which an insulating sheet 4 that exhibits conductivity by the presence of liquid is disposed between the conductive sheets 3 and 5. The conductive sheets 3 and 5 have through portions 31 and 51 through which at least one of the liquids passes. Furthermore, the liquid detection sensor 201 has a liquid-permeable sheet 203 that allows liquid to pass therethrough.

  Specifically, the liquid sensing sheet 1 includes a liquid-permeable insulating sheet 4 that exhibits conductivity by the presence of liquid, and conductive sheets 3 and 5 bonded to both surfaces of the insulating sheet 4. At least one of the conductive sheets 3 and 5 has penetrating portions 31 and 51 through which liquid passes. The insulating sheet 4 and the conductive sheets 3 and 5 are bonded together by an adhesive 7 that is dispersedly arranged on the entire bonding surface. By providing the adhesive member 202 and the liquid permeable sheet 203 having adhesiveness to the liquid sensing sheet 1 configured in this way, the liquid detection sensor 201 has disposed the liquid sensing sheet 1 inside the gauze of the adhesive bandage with gauze. Similar to configuration.

  Here, the “liquid” is a liquid sensing object by the liquid sensing sheet 1 and is not limited to a material or physical property as long as it is liquid. The liquid state means that the insulating sheet 4 is fluid enough to be impregnated. The kind of “liquid” may be pure water or water containing impurities, or an organic substance such as acid, alkali, oil, or organic solvent. The physical property of “liquid” may be any material that is liquefied at the ambient temperature in which the liquid sensing sheet 1 is used.

  As shown in FIG. 4, the liquid detection sensor 201 configured as described above can fix the liquid sensing sheet 1 to the installation target 302 by adhering an adhesive member to the installation target 302 such as a human body. Thereby, even when the installation target 302 vibrates or moves, the positional relationship between the installation target 302 and the liquid detection sensor 201 can be maintained. As a result, the liquid detection sensor 201 is less likely to be misaligned, and thus can reliably detect liquid leakage.

  The liquid detection sensor 201 is preferably sterilized. In particular, the liquid detection sensor 201 is preferably sterilized with ethylene oxide gas (EOG). Further, the liquid sensing sheet 1 can adopt any configuration as long as it has a function of sensing liquid. Details of the liquid sensing sheet 1 having a configuration in which the insulating sheet 4 is disposed between the conductive sheets 3 and 5 will be described later.

(Liquid detection sensor: terminal portions 2011a and 2011b)
As shown in FIG. 2, the liquid detection sensor 201 has two terminal portions 2011a and 2011b. These terminal portions 2011 a and 2011 b are formed by exposing a part of the conductive sheets 3 and 5 in the liquid sensing sheet 1. The tip portions of the terminal portions 2011a and 2011b are located outside the liquid-permeable sheet 203. As a result, since the terminal portions 2011a and 2011b are exposed to the outside during the preparation stage for installing the liquid sensing sheet 1, the operation of connecting to the signal line of the measuring device 301 is simplified. .

  In addition, since the terminal portions 2011a and 2011b are formed by using a part of the conductive sheets 3 and 5, the liquid detection sensor 201 can be formed more than when the terminal portions 2011a and 2011b are formed using new members. This makes it possible to reduce the number of parts. Further, the terminal portions 2011a and 2011b are arranged so as not to overlap each other in the thickness direction. Thereby, terminal part 2011a * 2011b makes it possible to perform the operation | work which connects the measuring apparatus 301 more easily.

  In addition, in this embodiment, although the structure which has arrange | positioned the terminal parts 2011a * 2011b so that it may not mutually overlap in the thickness direction is demonstrated, it is not limited to this. That is, as shown in FIG. 5, the terminal portions 2011 a and 2011 b may be arranged so as to overlap with each other through the insulating sheet 4 in the thickness direction. Furthermore, as shown in FIG. 6, the terminal portions 2011 a and 2011 b may be exposed to the outside from the adhesive member 202.

(Liquid detection sensor: adhesive member 202)
As shown in FIG. 3, the adhesive member 202 of the liquid detection sensor 201 has a rectangular shape in plan view and is formed in a flat plate shape having a predetermined thickness. Here, the predetermined thickness is such that the liquid detection sensor 201 can be bent or deformed along the shape of the installation target 302 and can be maintained in a deformed state when attached to the installation target 302. It means thickness. The liquid detection sensor 201 is not limited to a rectangular shape in plan view, and may be a polygonal shape such as a triangular shape or a pentagonal shape, or may be an elliptical shape or a circular shape.

  As the circular liquid detection sensor 201, as shown in FIG. 8, a configuration having terminal portions 2011a and 2011b arranged so as to overlap with each other through the insulating sheet 4 in the thickness direction is exemplified. In the case of this configuration, after the terminal portions 2011a and 2011b are raised from the adhesive surface of the adhesive member 202, one side is bent so that the terminal portions 2011a and 2011b are not in contact with each other, or an insulating material is interposed. 4 is connected to the terminal portions 2011a and 2011b by connecting the terminal portions 2011a and 2011b to the terminal portions 2011a and 2011b by sandwiching the terminal portions 2011a and 2011b with the connecting device (clip) at the end of the signal line connecting the measuring device 301. Can be made. Therefore, the overlapping of the terminal portions 2011a and 2011b makes it possible to reduce the size of the liquid detection sensor 201 as compared to the case where the terminal portions 2011a and 2011b are arranged in parallel.

(Liquid detection sensor: liquid permeable sheet 203)
The liquid permeable sheet 203 is formed in a rectangular shape that is the same shape as the outer shape of the liquid sensing sheet 1, and is formed in a size larger than the liquid sensing sheet 1. In addition, as long as it is a size larger than the liquid sensing sheet 1, it is not limited to a square shape.

  The liquid permeable sheet 203 covers one surface of the liquid sensing sheet 1 at the center, and is fixed to the adhesive 2022 at the outer periphery. As a result, the liquid-permeable sheet 203 covers the entire liquid sensing sheet 1 to prevent the liquid sensing sheet 1 from falling off. Further, the liquid permeable sheet 203 presses the liquid sensing sheet 1 from one surface side to the other surface side (adhesive material 2022 side), thereby pressing the other surface of the liquid sensing sheet 1 against the adhesive material 2022. 203 and the adhesive 2022 are firmly fixed.

  The liquid permeable sheet 203 has a function of transmitting liquid. Thereby, the liquid-permeable sheet 203 does not block the through portions 31 and 51 of the conductive sheets 3 and 5 when the liquid detection sensor 201 is installed by the adhesive material 2022, and one side of the liquid detection sheet 1. Protecting the liquid sensor facilitates the handling of the liquid detection sensor 201. More specifically, the liquid permeable sheet 203 is formed of gauze that allows liquid to permeate. Note that the liquid-permeable sheet 203 is not limited to a material or a shape as long as the liquid-permeable sheet 203 has a function of transmitting liquid. Examples include a nonwoven structure, a porous structure having open cells, a structure in which one or more holes are formed in a nonporous material, and a structure in which one or more slits are formed in a nonporous material.

  The thickness of the liquid-permeable sheet 203 is preferably 50 to 2000 μm. Moreover, it is preferable that the liquid-permeable sheet 203 has lyophilicity with respect to the liquid that is the sensing object. For example, if the liquid is water, the lyophilic property is referred to as hydrophilic. With a configuration having lyophilicity, even a small amount of liquid can pass through the liquid-permeable sheet 203, so that even a small amount of liquid can reach the liquid sensing sheet 1.

  In addition, the lyophilic property may be that the material of the liquid-permeable sheet 203 has lyophilic property, or a lyophilic layer is formed on the surface of the lyophobic material. For example, the liquid permeable sheet 203 may have a surfactant having surface activity with respect to the liquid attached to at least a part of the contact portion with the liquid in the liquid permeable structure. In this case, the liquid detection sensor 201 corresponding to the detection target such as water or oil can be obtained by properly using the type of the surfactant according to the type of the liquid to be detected.

  Furthermore, the liquid-permeable sheet 203 may have a coloring member whose color changes depending on the liquid. As a coloring member, the structure which sealed colorants, such as dye, in the capsule which melt | dissolves in the liquid which consists of solvents, such as water and oil, can be illustrated. In this case, when the capsule is melted by the liquid, the color of the liquid-permeable sheet 203 changes due to the flow of the sealed colorant. Therefore, the liquid detection sensor 201 can detect the liquid leakage visually. be able to.

  Furthermore, the liquid-permeable sheet 203 may be attached with a dissolving material (inorganic salts: sodium chloride, sodium sulfate, calcium chloride, magnesium hydroxide, etc.) that is dissolved and ionized in the liquid. In this case, even if the liquid itself is not conductive (such as oil), the dissolved material ionized by the liquid can change the insulating sheet 4 in the liquid sensing sheet 1 to be conductive.

  The liquid permeable sheet 203 may be further provided between the liquid sensing sheet 1 and the adhesive material 2022. In this case, the liquid-permeable sheet 203 is preferably equal to or smaller than the size of the adhesive material 2022 and smaller than or equal to the size of the liquid-permeable sheet 203 that covers one surface of the liquid-sensitive sheet 1. In this case, the liquid-sensitive sheet Since one side and the other side of 1 are sandwiched by the liquid-permeable sheet 203, it is possible to sense liquid from both sides of the liquid sensing sheet 1.

  Further, as shown in FIG. 7, the liquid-permeable sheet 203 may be provided so as to be wound around the liquid sensing sheet 1. In this case, since one surface and the other surface of the liquid sensing sheet 1 are covered with one liquid-permeable sheet 203, a process of covering one surface and the other surface of the liquid-sensitive sheet 1 with the liquid-permeable sheet 203 is performed. It can be performed in a process.

(Liquid detection sensor: adhesive member 202: adhesive material 2022)
The adhesive member 202 has a function of fixing at least a part of the liquid-permeable sheet 203. In the following description, the configuration in which the adhesive material 2022 is provided on the adhesive film 2023 will be described. However, the present invention is not limited to this, and the adhesive material 2022 is provided on the other surface of the liquid sensing sheet 1. Also good. As the adhesive material 2022 for fixing the liquid permeable sheet 203 and the liquid sensing sheet 1, acrylic, natural rubber, or synthetic rubber can be used.

(Liquid detection sensor: adhesive member 202: adhesive film 2023)
The adhesive material 2022 is formed on one surface of the adhesive film 2023. The adhesive film 2023 serves as a base film for the adhesive material 2022, and is disposed on the surface of the liquid sensing sheet 1 opposite to the liquid permeable sheet 203. The adhesive film 2023 is formed in a size larger than the liquid sensing sheet 1 and the terminal portions 2011a and 2011b. As a result, the adhesive film 2023 holds the adhesive material 2022 and covers the liquid sensing sheet 1 and the terminal portions 2011a and 2011b, thereby protecting the liquid sensing sheet 1 and the terminal portions 2011a and 2011b from external force due to impact and rubbing. It is supposed to be. Furthermore, the adhesive film 2023 increases the strength of the liquid detection sensor 201.

  The adhesive film 2023 may have a through hole. Further, the adhesive film 2023 may have a through hole to which a surfactant or a dissolving member that dissolves into a liquid and ionizes is attached.

  Further, the adhesive film 2023 may be formed of paper or non-woven fabric, or may be formed of an epoxy resin, a polyester resin, an acrylic resin, a phenol resin, a urethane resin, or a mixture thereof. . In addition, although the thickness of the film 2023 for adhesion is 25-200 micrometers, it does not need to be specifically limited and can be set suitably.

(Liquid detection sensor: adhesive member 202: release sheet 2024)
The adhesive member 202 may have a release sheet 2024 that covers the adhesive material 2022 as shown in FIG. The release sheet 2024 makes it possible to maintain the adhesiveness of the adhesive material 2022 over a long period of time, and to exhibit the adhesiveness of the liquid detection sensor 201 only when necessary, so that the portability of the liquid detection sensor 201 is achieved. Make it excellent. Furthermore, the release sheet 2024 can protect both surfaces of the liquid sensing sheet 1 and the terminal portions 2011a and 2011b with the adhesive film 2023.

(Manufacturing method of liquid detection sensor)
A method of manufacturing the liquid detection sensor 201 with the above configuration will be described. A method for manufacturing the liquid sensing sheet 1 will be described later.

  First, a long adhesive film 2023 having a width of several times or several tens of times that of the liquid detection sensor 201 is prepared in a rolled state. The adhesive film 2023 is unwound, and the adhesive material 2022 is applied to the entire top surface (one surface) of the adhesive film 2023. Then, the liquid sensing sheet 1 that is cut into a size corresponding to the width dimension and the length dimension of the liquid detection sensor 201 and formed with the terminal portions 2011a and 2011b is placed in the width direction and the length direction of the adhesive film 2023. The As a result, a plurality of liquid sensing sheets 1 are arranged on the adhesive film 2023 in a matrix in the width direction and the length direction.

  Thereafter, the liquid-permeable sheet 203 cut out to a size larger than the liquid sensing sheet 1 is placed so as to cover each liquid sensing sheet 1. Further, if necessary, a release sheet 2024 having the same size as the adhesive film 2023 is covered from above the liquid-permeable sheet 203. When the liquid permeable sheet 203 is pressed by a pressing device (not shown), the liquid sensing sheet 1 and the liquid permeable sheet 203 are fixed to the adhesive material 2022 on the adhesive film 2023. Thereby, the liquid sensing sheet 1 and the adhesive member 202 are integrated. When an intermediate product sheet in which a plurality of liquid detection sensors 201 are arranged in a matrix is created in this way, a single liquid detection sensor 201 is created by cutting or punching the intermediate product sheet.

(Application example of liquid detection sensor)
The sheet-like liquid detection sensor 201 manufactured as described above is collected in a stacked state in which a plurality of sheets are collected. And these liquid detection sensors 201 are stored in storage means, such as a worker's pocket and a tool case. That is, the liquid detection sensor 201 can be stored while being carried by an operator, such as a bandage with gauze.

  As shown in FIG. 4, when there is an installation target 302 of a device or a place where it is desired to detect the presence or absence of liquid leakage, first, if the liquid detection sensor 201 includes the release sheet 2024, the release sheet 2024 is peeled off and the release is performed. If the liquid detection sensor 201 does not include the sheet 2024, it is prepared as it is.

  Next, the terminal portions 2011a and 2011b are pulled up from the surface on which the adhesive material 2022 is formed, and are sandwiched between clips attached to the ends of the signal lines of the measuring device 301. The liquid detection sensor 201 is moved so that the formation surface of the adhesive material 2022 contacts the installation target 302, and the liquid detection sensor 201 is pressed against the installation target 302. Thereby, the liquid detection sensor 201 adheres in a state where the liquid detection sheet 1 is in contact with a desired portion of the installation target 302 via the liquid-permeable sheet 203. As a result, even when the installation target 302 moves or vibrates, the liquid detection sensor 201 continues to detect liquid leakage for a long period without causing a positional shift.

  When leakage occurs in the installation target 302, the liquid passes through the liquid-permeable sheet 203 and adheres to the surface of the liquid sensing sheet 1 as shown in FIG. The liquid passes through the passage hole 21 and the through portion 31 and reaches one surface of the insulating sheet 4, and permeates into the insulating sheet 4 by the liquid-permeable structure of the insulating sheet 4. And when a liquid reaches | attains the other surface of the insulating sheet 4, the insulating sheet 4 will exhibit electroconductivity and between the electroconductive sheets 3 * 5 will switch from an insulation state to a conductive state. As a result, the measurement device 301 in FIG. 4 detects a change in electrical resistance, thereby detecting liquid leakage.

  Thereafter, the liquid detection sensor 201 that senses the liquid is peeled off from the installation target 302 by the operator and replaced with an unused liquid detection sensor 201. In this way, the liquid detection sensor 201 can be used in a disposable use form such as a gauze bandage. Note that the used liquid detection sensor 201 may be reused by drying the soaked liquid.

  The installation target 302 is exemplified by a human arm or a leg when the liquid detection sensor 201 is applied to medical treatment. In this case, the indwelling needle may come off during treatment such as dialysis, blood transfusion, infusion, etc., and blood / drug solution may leak. However, if the liquid detection sensor 201 is attached to the puncture part, the blood / drug solution leaks. Can be detected. At this time, since the liquid detection sensor 201 is directly attached to the puncture portion, even a small amount of liquid leakage can be detected.

(Liquid detection sensor: Liquid detection sheet 1)
Next, the liquid detection sheet 1 used for the liquid detection sensor 201 will be described.
As shown in FIG. 9, the liquid sensing sheet 1 includes a liquid-permeable insulating sheet 4 that exhibits conductivity by the presence of liquid, and conductive sheets 3 and 5 bonded to both surfaces of the insulating sheet 4. Yes. The conductive sheets 3 and 5 have through portions 31 and 51 that allow liquid to pass therethrough. The insulating sheet 4 and the conductive sheets 3 and 5 are bonded together by an adhesive 7 that is dispersedly arranged on the entire bonding surface. In other words, the liquid sensing sheet 1 has a configuration in which the insulating sheet 4 is disposed between the two conductive sheets 3 and 5 in a joined state.

  Since the liquid sensing sheet 1 configured as described above can bond the insulating sheet 4 and the conductive sheets 3 and 5 over the entire surface with an adhesive distributed over the entire bonding surface, a desired size or Even if cut into a shape, it can be used as a liquid sensing sheet having the same sensing performance and bonding strength. Thereby, since the liquid sensing sheet 1 can change a size and a shape arbitrarily, the freedom degree of application object is high.

  In addition, the liquid sensing sheet 1 is bonded to the long insulating sheet 4 and the conductive sheets 3 and 5 because the insulating sheet 4 and the conductive sheets 3 and 5 are bonded to each other by an adhesive distributed over the entire bonding surface. It is also possible to manufacture continuously by applying the agent. Furthermore, the continuously manufactured liquid sensing sheet 1 can be shipped and stored as a short type liquid sensing sheet trimmed to a predetermined length by cutting in the middle of production, and the long liquid sensing sheet. It can also be shipped and stored as a liquid sensing roll 10 in which 1 is wound into a roll. That is, the liquid sensing sheet 1 has a configuration suitable for mass production.

  The liquid sensing sheet 1 includes two protective sheets 2 and 6. The protective sheets 2 and 6 are respectively disposed on the surfaces of the conductive sheets 3 and 5 opposite to the insulating sheet 4 so as to be positioned on the front surface (one surface) and the back surface (other surface) of the liquid sensing sheet 1. Yes. These protective sheets 2 and 6 have a function of protecting the liquid sensing sheet 1 from external force due to impact and rubbing, increasing the strength of the liquid sensing sheet, and insulating functions. These protective sheets 2 and 6 have passage holes 21 and 61 that overlap the through portions 31 and 51 of the conductive sheets 3 and 5.

(Liquid detection sensor: insulating sheet 4 of the liquid detection sheet 1)
The insulating sheet 4 disposed at the center in the thickness direction of the liquid sensing sheet 1 has a liquid-permeable structure that exhibits electrical conductivity due to the presence of the liquid and allows the liquid to pass therethrough. That is, the insulating sheet 4 is configured to change from insulating to conductive as a whole by the permeation of liquid.

  The “liquid permeable structure” provided in the insulating sheet 4 is not limited to the material and shape as long as it is a structure that allows the liquid that is the sensing object to pass through. Examples include a nonwoven structure, a porous structure having open cells, a structure in which one or more holes are formed in a nonporous material, and a structure in which one or more slits are formed in a nonporous material. When the insulating sheet 4 is non-woven fabric or paper, even a small amount of liquid penetrates into the insulating sheet 4 due to capillary action and changes from an insulating state to a conductive state. 1 can be used.

  The material of the insulating sheet 4 is not particularly limited as long as it is a material having a large electric resistance when not in contact with a liquid.

  Examples of the material of the insulating sheet 4 include cellulose such as cloth and paper, ceramic, and engineering plastic. Examples of engineering plastics include polypropylene, crosslinked polyethylene, polyester, polybenzimidazole, aramid, polyimide, polyimideamide, polyetherimide, polyphenylene sulfide (PPS), and polyethylene naphthalate (PEN).

Specifically, a nonwoven fabric made of a polyester resin manufactured by Unitika Ltd. (registered trademark: MARIX) can be used for the insulating sheet 4. This nonwoven fabric has hydrophilicity because the resin for adhering the polyester fibers is a water-soluble acrylic resin. In addition, the manufacturing method of said nonwoven fabric is a spun bond method. When the nonwoven fabric product number is # 20507WTD, the basis weight is 50 g / m ² and the average thickness is 155 μm. When the nonwoven fabric product number is # 20604FLD, the basis weight is 60 g / m ² and the average thickness is 150 μm. When the nonwoven fabric product number is # 10606WTD, the basis weight is 60 g / m ² and the average thickness is 215 μm (with bulkiness).

  The thickness of the insulating sheet 4 is preferably 1 to 5000 μm. The insulating sheet 4 is preferably lyophilic with respect to the liquid that is the sensing object. For example, if the liquid is water, the lyophilic property is referred to as hydrophilic. In the configuration having lyophilicity, even a small amount of liquid penetrates into the insulating sheet 4 and changes from an insulating state to a conductive state. It can be set as the liquid sensing sheet 1 which shortens time.

  In addition, the lyophilic property may be that the material of the insulating sheet 4 has lyophilic property, or a lyophilic layer is formed on the surface of the lyophobic material. For example, in the insulating sheet 4, a surfactant having surface activity with respect to the liquid may be attached to at least a part of the contact portion with the liquid in the liquid-permeable structure. In this case, the liquid sensing sheet 1 that can select the sensing target such as water or oil can be obtained by properly using the type of the surfactant according to the type of the sensing target liquid.

  Furthermore, the insulating sheet 4 may have a coloring member whose color changes depending on the liquid. As a coloring member, the structure which sealed colorants, such as dye, in the capsule which melt | dissolves in the liquid which consists of solvents, such as water and oil, can be illustrated. In this case, when the capsule is melted by the liquid, the color of the insulating sheet 4 changes due to the flow of the sealed colorant, so that the liquid sensing sheet 1 that can visually detect the liquid leakage is used. Can do.

  Furthermore, the insulating sheet 4 may be attached with a dissolving material (inorganic salts: sodium chloride, sodium sulfate, calcium chloride, magnesium hydroxide, etc.) that is dissolved and ionized in a liquid. In this case, even if the liquid itself has no conductivity (such as oil), the dissolved material ionized by the liquid can change the insulating sheet 4 to be conductive.

(Liquid detection sensor: Conductive sheet 3.5 of liquid detection sheet)
Conductive sheets 3 and 5 having conductivity are bonded to both surfaces of the insulating sheet 4. The lower limit of the thickness of the conductive sheets 3 and 5 is 0.05 μm, and the upper limit of the thickness is 200 μm. In addition, when the conductive sheets 3 and 5 are formed by sputtering or vapor deposition, a thickness of 0.05 to 1 μm is preferable. When the conductive sheets 3 and 5 are formed by the conductive ink printing method, a thickness of 2 to 200 μm is preferable. When the conductive sheets 3 and 5 are formed of metal foil, the thickness is preferably 2 to 100 μm.

  In addition, the conductive sheets 3 and 5 have through portions 31 and 51 that allow liquid to pass therethrough. The penetration parts 31 and 51 are formed by circular holes. What is necessary is just to determine suitably the hole diameter (diameter) in the penetration parts 31 and 51 by a test, experiment, etc. with the kind of liquid. Moreover, although the hole area ratio of the penetration parts 31 and 51 should just be the range of 1 to 90%, it is preferable to adjust suitably according to a use.

  In addition, the hole shape of penetration part 31 * 51 may be polygonal shapes, such as a long hole shape, an ellipse shape, and a triangle, a quadrangle, other than circular shape. The hole sizes of the through-portions 31 and 51 may be set to an extent that causes capillary action, or may be larger than liquid droplets. Moreover, the penetration parts 31 and 51 may be a combination of various shapes and sizes. For example, the outer diameter of a circular shape, an elliptical shape, a triangular shape, a quadrangular shape, a pentagonal shape, a hexagonal shape or the like formed by punching is preferably 0.1 to 30 mm.

  Further, the through portions 31 and 51 may be slits. The shape of the slit may be a straight line,-, =, a cross, or a V mark. The slit length is preferably 3 to 5 mm. Even in the case of the slit, it becomes possible to promote the permeation of the liquid by the capillary phenomenon. In other words, the penetration parts 31 and 51 should just be formed by at least one of the hole and the slit. As a result, the conductive sheets 3 and 5 can be made into the liquid sensing sheet 1 having various sensitivities by one or more combinations of holes and slits.

  Specifically, as shown in FIG. 10, the liquid sensing sheet 1 may have circular through portions 31 and 51 arranged in a matrix in the longitudinal direction and the width direction. In addition, it is preferable that arrangement | positioning is arrange | positioned equally in the whole surface. In addition, as shown in FIG. 11, the liquid sensing sheet 1 may have elongated hole-shaped through portions 31 and 51 formed at both ends in the width direction and arranged in the longitudinal direction with a predetermined interval. Further, as shown in FIG. 12, the liquid sensing sheet 1 may have rectangular through portions 31 and 51 arranged in a lattice shape including a width direction, a longitudinal direction, and an inclination direction. According to this configuration, the work of cutting into a predetermined shape is facilitated. Further, as shown in FIG. 13, the liquid sensing sheet 1 may have circular through portions 31 and 51 and slit through portions 31 and 51 arranged alternately.

  Furthermore, the liquid sensing sheet 1 may be a combination of FIGS. 10 to 13 or the hole portion may be replaced with a slit. When all the penetrating parts 31 and 51 are slits, the penetrating parts 31 and 51 are formed by cutting the conductive sheets 3 and 5 using a plurality of blade parts formed on a base member such as a roll. be able to. Thereby, since the punching waste of a hole part does not remain like the case where a hole is formed by punching out the conductive sheets 3 and 5, generation of waste can be suppressed to the minimum.

  The conductive sheets 3 and 5 may be made of any material as long as they have conductivity, but are preferably metals such as aluminum and copper. The metal material for forming the conductive sheets 3 and 5 is nickel, copper, silver, tin, gold, palladium, aluminum, chromium, titanium, zinc, or an alloy containing two or more of these. There may be.

  The conductive sheets 3 and 5 are preferably metal layers. Here, the metal layer is a concept including a metal foil and a metal thin film. When the conductive sheets 3 and 5 are metal layers, the gaps between the dispersed adhesives 7 are exposed surfaces of the conductive sheets 3 and 5, and the exposed surfaces are flat metal layers (conductive sheets 3). Since 5), the presence or absence of the conductive state can be sensed in the entire portion excluding the through portions 31 and 51.

  Furthermore, the conductive sheets 3 and 5 are particularly preferably a metal foil. In this case, the electrical resistance is small and the sensing time can be shortened.

  The conductive sheets 3 and 5 are not limited to metal foils by rolling and metal foils by electrolysis (such as special electrolytic copper foils), but vacuum deposition, sputtering, CVD, MO (metal organic), plating, printing A metal thin film formed by, for example, may be used.

  Moreover, the conductive sheets 3 and 5 may be formed of a conductive adhesive. In this case, since the conductive sheets 3 and 5 can be formed by applying a conductive adhesive, the liquid sensing sheet 1 can be easily obtained. The conductive adhesive is a mixture composed of conductive particles and an adhesive resin, and is an adhesive that can be heat-pressed at 100 to 200 ° C. The conductive particles are metal powder or low melting point metal powder having an average particle diameter of 2 to 50 μm, and 10 to 400 parts by weight are blended with 100 parts by weight of the adhesive resin.

  Further, as shown in FIG. 9, the liquid sensing sheet 1 is arranged so that the through portions 31 and 51 of one conductive sheet 3 and the other conductive sheet 5 do not overlap each other. That is, the penetration part 31 of one conductive sheet 3 is completely blocked by the other conductive sheet 5, and the penetration part 51 of the other conductive sheet 5 is completely blocked by the one conductive sheet 3. It has been in a state. Thereby, for example, since the liquid that has permeated through the insulating sheet 4 from the penetrating portion 31 of the one conductive sheet 3 is blocked by the other conductive sheet 5, the liquid sensing sheet 1 can be reliably sensed. In addition, as for the liquid sensing sheet 1, the penetration parts 31 * 51 of the electroconductive sheets 3 * 5 may overlap partially.

  In addition, it is preferable that the conductive sheets 3 and 5 have the same thickness and material, and the shape, size, and open area ratio of the through portions 31 and 51 are the same. Thereby, since the same sensing performance is exhibited in any surface of the liquid sensing sheet 1, it is possible to eliminate the necessity of the work of attaching carefully to the surface that senses the liquid to be sensed.

  One conductive sheet 3 and the other conductive sheet 5 may have different configurations. For example, the combination shown in FIGS. When the conductive sheets 3 and 5 have different configurations, the sensing performance can be varied depending on the surface of the conductive sheets 3 and 5, so that the application target of the liquid as the sensing object can be expanded. The liquid sensing sheet 1 having two types of sensitivity can be obtained.

  When the sensing performance of the conductive sheets 3 and 5 is made different, the conductive sheets 3 and 5 can be identified by color coding or symbol notation so that an operator can distinguish the sensing performance. It is preferable. Further, as shown in FIG. 14, the liquid sensing sheet 1 may have through portions 31 and 51 in either one of the conductive sheets 3 and 5. That is, the liquid sensing sheet 1 only needs to have the through portions 31 and 51 in at least one of the conductive sheets 3 and 5.

  In the through portions 31 and 51 in the conductive sheets 3 and 5, a surfactant having surface activity with respect to the liquid may be attached to at least a part of the contact portion with the liquid. The same surfactant as that used for the insulating sheet 4 can be used. In this case, since the liquid can easily reach the insulating sheet 4 through the penetrating portions 31 and 51 by the surfactant, the insulating sheet 4 can be changed from the insulating state to the conductive state even with a small amount of liquid. It becomes possible. Further, by properly using the type of the surfactant according to the type of the liquid to be sensed, for example, the liquid sensing sheet 1 can be selected such as water or oil. In the case of oil, since it is insulative, it is necessary to attach an ionizing melting member to the through portions 31 and 51 and the insulating sheet. The surfactant may be attached to the conductive sheets 3 and 5 and the insulating sheet 4 or may be attached to any one of them.

(Liquid detection sensor: Adhesive 7 for liquid detection sheet)
The insulating sheet 4 and the conductive sheets 3 and 5 configured as described above are bonded together by an adhesive 7 that is dispersedly arranged on the entire bonding surface. Here, “distributed arrangement over the entire joint surface” is a concept including a plurality of divided linear shapes, continuous linear shapes, and a plurality of dotted shapes. The adhesive 7 is preferably dispersed. Moreover, the adhesive agent 7 may be arrange | positioned avoiding the penetration parts 31 * 51, and a part may overlap and it may be arrange | positioned.

  If the kind of the adhesive agent 7 is demonstrated in detail, water glass will be illustrated as an inorganic type adhesive agent. Examples of the natural adhesive include casein adhesive, natural rubber, natural rubber latex, starch, glue, and fibrin. Examples of the synthetic adhesive include solvent-based, water-soluble, and hot-melt (hereinafter sometimes referred to as “HM”) systems.

  Specifically, solvent-based synthetic adhesives include acrylic resin-based, acrylic resin-based adhesives, α-olefin-based adhesives, urethane resin-based adhesives, epoxy resin-based adhesives, and vinyl chloride resin solvent-based adhesives. , Chloroprene rubber adhesive, cyanoacrylate adhesive, silicone adhesive, styrene-butadiene rubber solution adhesive, nitrile rubber adhesive, nitrocellulose adhesive, modified silicone adhesive, polyimide adhesive, poly Vinyl acetate resin solution adhesive, polystyrene resin solvent adhesive, polyvinyl alcohol adhesive, polyvinyl pyrrolidone resin adhesive, polyvinyl butyral resin adhesive, polybenzimidazole adhesive, polymethacrylate resin solution adhesive Is exemplified.

  As water-based synthetic adhesives, ether cellulose, acrylic resin emulsion adhesive, urethane resin emulsion adhesive, ethylene-vinyl acetate resin emulsion adhesive, epoxy resin emulsion adhesive, vinyl acetate resin emulsion adhesive, Examples include aqueous polymer-isocyanate adhesives, styrene-butadiene rubber latex adhesives, phenol resin adhesives, modified silicone adhesives, melamine resin adhesives, urea resin adhesives, and resorcinol adhesives. .

  Examples of HM synthetic adhesives include ethylene-vinyl acetate resin hot melt adhesives, reactive hot melt adhesives, polyamide resin hot melt adhesives, polyurethane resin hot melt adhesives, and polyolefin resin hot melt adhesives. The

  Among the adhesives exemplified above, the HM system is preferable. The reason for this is that it contains no solvent or water compared to other adhesives, and the amount when cured and the amount before curing do not change, so the amount of adhesive can be reduced, so it can be applied according to the pattern. Because it can. Pattern coatings such as HM-based ethylene-vinyl acetate resin hot melt adhesives, polyamide resin hot melt adhesives, and polyurethane resin hot melt adhesives are preferred.

  The adhesive 7 can be a conductive adhesive. When a conductive adhesive is used for the adhesive 7, the adhesive 7 itself can be made conductive, so that the sensing performance of the liquid sensing sheet 1 can be improved. As the conductive adhesive, either an isotropic conductive adhesive or an anisotropic conductive adhesive may be used.

(Liquid detection sensor: Protection sheet for liquid detection sheet 2.6)
Protective sheets 2 and 6 are respectively disposed on the surfaces of the conductive sheets 3 and 5 opposite to the insulating sheet 4. These protective sheets 2 and 6 cover the conductive sheets 3 and 5 so that they are not directly exposed to the outside, thereby protecting the liquid sensing sheet 1 from external force due to impact and rubbing, increasing the strength of the liquid sensing sheet, and insulating it. Has a function. The protective sheets 2 and 6 have passage holes 21 and 61 that overlap the through portions 31 and 51 of the conductive sheets 3 and 5. The passage holes 21 and 61 may have any shape or size that overlaps with the through portions 31 and 51. The passage holes 21 and 61 may be attached with the above-mentioned surfactant or a dissolving member that dissolves into a liquid and is ionized.

  The protective sheets 2 and 6 may be formed of paper or non-woven fabric, or may be formed of an epoxy resin, a polyester resin, an acrylic resin, a phenol resin, a urethane resin, or a mixture thereof. In addition, although the thickness of the protective sheets 2 and 6 is 5-200 micrometers, it does not need to be specifically limited and can be set suitably. In addition, when the protective sheets 2 and 6 are formed of a PET film, it is desirable that the surface of the PET film is subjected to a hydrophilic treatment. The hydrophilic treatment is a hydrophilic resin coat, corona treatment, plasma treatment, or the like.

  The protective sheets 2 and 6 and the conductive sheets 3 and 5 are bonded by an adhesive 8. The adhesive 8 may be the same material as the adhesive 7 described above, or may be a different material. Further, the adhesive 8 may be arranged in a distributed manner, or may be arranged on the entire joint surface between the protective sheets 2 and 6 and the conductive sheets 3 and 5. When the conductive sheets 3 and 5 are formed by applying a conductive paste to the protective sheets 2 and 6, the adhesive 8 can be omitted.

(Liquid detection sensor: Liquid sensing sheet manufacturing method)
In the above configuration, a method for manufacturing the liquid sensing sheet 1 will be described. In addition, the numerical value in description of a manufacturing method is an illustration, and can be changed suitably. First, a 12 μm PET (Polyethylene terephthalate) film, paper, and nonwoven fabric are prepared as the insulating sheet 4. In the case of a PET film, it is processed so that a plurality of holes and slits are evenly dispersed so as to have a liquid-permeable structure.

  6 μm copper foil and 9 μm aluminum foil are prepared as the conductive sheets 3 and 5, and 12 μm PET film, paper, and nonwoven fabric are prepared as the protective sheets 2 and 6. Then, the protective sheets 2 and 6 are joined to the conductive sheets 3 and 5 via the adhesive 8. Thereafter, through holes 31 and 51 and through holes 21 and 61 are formed by drilling and slitting the integrated conductive sheets 3 and 5 and protective sheets 2 and 6.

  Next, the adhesive 7 is evenly dispersed and applied to the surfaces of the conductive sheets 3 and 5 with the protective sheets 2 and 6 subjected to drilling and slit processing. The conductive sheets 3 and 5 with the protective sheets 2 and 6 are laminated on the insulating sheet 4 so that the surface to which the adhesive 7 is applied contacts the insulating sheet 4 described above. In addition, lamination | stacking of the insulating sheet 4 and the electroconductive sheets 3 * 5 may be performed at the same timing with respect to both surfaces of the insulating sheet 4, and may be performed at a different timing. Further, the adhesive 7 may be applied to the insulating sheet 4. Thereafter, the laminated member of the protective sheets 2 and 6, the conductive sheets 3 and 5, and the insulating sheet 4 is heated to cure the adhesive 7, whereby the liquid sensing sheet 1 of FIG. 10 is manufactured.

  The manufacturing method described above may be performed in batch units by dividing the protective sheets 2 and 6, the conductive sheets 3 and 5, and the insulating sheet 4 into predetermined dimensions, or by forming a long strip. It may be performed continuously. In addition, the manufacturing method described above has an advantage that the thin liquid sensing sheet 1 can be manufactured, and any position of the liquid sensing sheet 1 can be cut and used as a sensor, that is, it can be manufactured with high yield.

(Liquid detection sensor: Modification of liquid detection sheet)
In this embodiment, although the case where the electroconductive sheets 3 and 5 and the insulating sheet 4 were joined using the adhesive agent 7 was demonstrated, it is not limited to this. More specifically, as shown in FIG. 15, the liquid sensing sheet 101 includes a liquid-permeable insulating sheet 4 that exhibits conductivity by the presence of liquid, and a conductive adhesive bonded to both surfaces of the insulating sheet 4. The conductive sheets 3 and 5 may be provided, and at least one of the conductive sheets 3 and 5 may be configured to have through portions 31 and 51 that allow liquid to pass therethrough.

  According to the above configuration, since the conductive sheets 3 and 5 made of a conductive adhesive and the insulating sheet 4 can be bonded over the entire surface, even if the desired size and shape are cut out, the same sensing performance and It can be used as a liquid sensing sheet 101 having bonding strength. In other words, in the case of the configuration in which the peripheral edge of the sheet is joined with an adhesive as in the conventional case, the size and shape are limited. However, according to the above configuration, the size and shape can be arbitrarily changed. The liquid sensing sheet 101 can have a high degree of freedom. Furthermore, since the conductive sheets 3 and 5 themselves can be bonded to the insulating sheet 4, it is not necessary to use the adhesive 7 in FIG. 9, so that the liquid sensing sheet 101 having a simple configuration can be easily obtained. Can do.

  Here, the conductive adhesive for the conductive sheets 3 and 5 is preferably an isotropic conductive adhesive, but may be an anisotropic conductive adhesive. The isotropic conductive adhesive ensures an electrically conductive state in all three directions including the thickness direction, the width direction, and the longitudinal direction of the conductive sheets 3 and 5. The conductive adhesive is formed by adding a conductive filler to the adhesive. If flame retardancy is required, add a flame retardant.

  When a conductive adhesive is applied to the conductive sheets 3 and 5 of the liquid sensing sheet 1, the lower limit of the thickness of the conductive sheets 3 and 5 is 5 μm, and preferably 10 μm. Moreover, the upper limit of thickness is 100 micrometers, and 50 micrometers is preferable.

  The adhesive contained in the conductive adhesive is an adhesive resin, such as a thermoplastic resin such as polystyrene, vinyl acetate, polyester, polyethylene, polypropylene, polyamide, rubber, acrylic, phenolic, It consists of thermosetting resins such as epoxy, urethane, melamine, and alkyd. The adhesive may be a single substance or a mixture of the above resins. The adhesive may further contain a tackifier. Examples of the tackifier include tackifiers such as fatty acid hydrocarbon resins, C5 / C9 mixed resins, rosin, rosin derivatives, terpene resins, aromatic hydrocarbon resins, and thermally reactive resins.

  Part or all of the conductive filler added to the conductive adhesive is formed of a metal material. For example, conductive fillers include copper powder, silver powder, nickel powder, silver coated copper powder (Ag coated Cu powder), gold coated copper powder, silver coated nickel powder (Ag coated Ni powder), and gold coated nickel powder. The metal powder can be produced by an atomizing method, a carbonyl method, or the like. In addition to the above, particles obtained by coating a metal powder with a resin and particles obtained by coating a resin with a metal powder can also be used. Furthermore, one or more kinds of conductive fillers may be mixed and added to the conductive adhesive. The conductive filler is preferably Ag-coated Cu powder or Ag-coated Ni powder. This is because conductive particles having stable conductivity can be obtained from an inexpensive material.

  The conductive filler is added in the range of 10 to 400 wt% with respect to the adhesive resin. The average particle size of the conductive filler is preferably in the range of 2 to 50 μm, but an optimal value may be selected depending on the thickness of the conductive sheets 3 and 5. The shape of the metal filler may be any of a spherical shape, a needle shape, a fiber shape, a flake shape, and a resin shape.

  As the flame retardant, a non-halogen flame retardant is preferable from an environmental problem. Nitrogen flame retardant such as melamine cyanurate and melamine polyphosphate, metal hydrate such as magnesium hydroxide and aluminum hydroxide, or phosphate ester, Phosphorus flame retardants such as red phosphorus can be mentioned, but when heat resistance is required, melamine cyanurate and magnesium hydroxide are preferable.

  In the above detailed description, the present invention has been described mainly with respect to characteristic parts so that the present invention can be more easily understood. However, the present invention is not limited to the embodiments described in the above detailed description, and other implementations are possible. It can also be applied to forms and its scope should be interpreted as widely as possible.

  The terms and terminology used in the present specification are used to accurately describe the present invention, and are not used to limit the interpretation of the present invention. Moreover, it would be easy for those skilled in the art to infer other configurations, systems, methods, and the like included in the concept of the present invention from the concept of the invention described in this specification. Accordingly, the description of the claims should be regarded as including an equivalent configuration without departing from the technical idea of the present invention. In addition, in order to fully understand the object of the present invention and the effects of the present invention, it is desirable to fully consider the literatures already disclosed.

DESCRIPTION OF SYMBOLS 1 Liquid sensing sheet 2 Protective sheet 3 Conductive sheet 4 Insulating sheet 5 Conductive sheet 6 Protective sheet 7 Adhesive 8 Adhesive 21 Permeation hole 31 Penetration part 51 Penetration part 61 Permeation hole 101 Liquid sensing sheet 201 Liquid detection sensor 202 Adhesive member 203 Liquid-permeable sheet 2022 Adhesive material 2023 Adhesive film

Claims (8)

A liquid sensing sheet in which an insulating sheet that exhibits electrical conductivity due to the presence of liquid is disposed between the conductive sheets;
A liquid detection sensor having an adhesive member provided on the liquid detection sheet. Furthermore, it has a liquid-permeable sheet that covers one surface of the liquid sensing sheet,
At least one of the conductive sheets has a penetrating portion that allows the liquid to pass through,
The liquid detection sensor according to claim 1, wherein the adhesive member includes an adhesive material that fixes the liquid-permeable sheet.   The liquid detection sensor according to claim 2, further comprising a liquid-permeable sheet that covers the other surface of the liquid detection sheet. Furthermore, it has a liquid-permeable sheet that covers the periphery of the liquid sensing sheet,
At least one of the conductive sheets has a penetrating portion that allows the liquid to pass through,
The liquid detection sensor according to claim 1, wherein the adhesive member includes an adhesive material that fixes the liquid-permeable sheet.   The liquid detection sensor according to claim 2, wherein the adhesive member includes a release sheet that covers the adhesive material.   The liquid detection sensor according to claim 5, further comprising a terminal portion formed by exposing a part of the conductive sheet.   The liquid detection according to claim 6, wherein the terminal portion of one of the conductive sheets and the terminal portion of the other conductive sheet are arranged so as not to overlap each other in the thickness direction. sensor. An insulating sheet having a liquid-permeable structure that exhibits electrical conductivity by the presence of liquid; and an electrically conductive sheet bonded to both surfaces of the insulating sheet, wherein at least one of the conductive sheets penetrates the liquid A liquid sensing sheet joined by an adhesive dispersed and disposed on the entire joining surface, and the insulating sheet and the conductive sheet,
A liquid detection sensor having an adhesive member provided on the liquid detection sheet.

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