JP2018124079A - Pressure sensitive sensor sheet, manufacturing method therefor and overturning detection system - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a pressure-sensitive sensor sheet that can be suitably used for a fall detection system capable of accurately detecting that an observer has fallen. A pressure-sensitive sensor sheet according to the present invention includes a plurality of electrode pairs in which a first electrode and a second electrode are a pair of electrode pairs, and a pair of electrode pairs on both sides of a flexible sheet. One electrode and the second electrode are arranged in a state of being opposed to each other with the flexible sheet interposed therebetween, and a pair of electrode pairs and a flexible sheet portion existing between opposed surfaces of the electrodes constituting the electrode pair. A plurality of formed pressure-sensitive sensors are formed. [Selection] Figure 1

Description

  The present invention relates to a pressure-sensitive sensor sheet, a manufacturing method thereof, and a fall detection system.

  In homes, nursing homes, hospitals and nursing homes, etc., it is necessary to monitor the elderly, infants, patients and residents (hereinafter referred to as “observers”) sufficiently so that they are not in danger. Family members and caregivers regularly check whether they are in a safe state.

  At homes, nursing homes, hospitals, nursing homes, etc., elderly people, infants, patients, and residents (hereinafter referred to as “observers”) are seriously affected by falls. Can be life-threatening and early detection is important.

  On the other hand, for example, in a care facility, a hospital, and a nursing home, it is burdensome for the caregiver to regularly look around the person to be observed, and in particular, in a hospital and a nursing home, a single caregiver has multiple patients or There is a problem that the burden on the residents is large, and there is a need for a system that detects the fall of the person being observed.

  Therefore, in Patent Literature 1, an acquisition unit that acquires a distance image and an IR image of a space to be detected from a TOF sensor, a size of the object based on the acquired distance image and the IR image, A determination unit configured to determine a movement of the object for a predetermined time and a pattern, a color, or a shade of the object; a size of the determined object; a movement of the object for a predetermined time; There has been proposed a fall detection processing device having an estimation unit that estimates whether the movement of the object is a fall of a person according to a pattern, color, or shade.

JP, 2006-676413, A

  However, the fall detection processing apparatus has a problem that the fall detection accuracy of the observer is low, and the presence or absence of the fall of the observer cannot be accurately grasped.

  The present invention provides a fall detection system that can accurately detect that an observer has fallen. The present invention also provides a pressure-sensitive sensor sheet that can be suitably used for a fall detection system and the like, and a method for manufacturing the same.

  The pressure-sensitive sensor sheet according to the present invention includes a plurality of electrode pairs each having a first electrode and a second electrode as a pair of electrodes, the first electrode having a pair of electrodes on both sides of the flexible sheet, and the above-described first electrode and the second electrode. A feeling formed by a pair of electrode pairs and a flexible sheet portion existing between the opposing surfaces of the electrodes constituting the electrode pair, disposed in a state where the second electrodes face each other across the flexible sheet. A plurality of pressure sensors are formed.

The method of manufacturing a pressure-sensitive sensor sheet according to the present invention includes a long first electrical insulating sheet and a plurality of first electrical insulating sheets formed on one surface of the first electrical insulating sheet and arranged in a predetermined pattern. While sticking the 1st electrode sheet which has the 1st electrode pattern in which the 1st electrode group containing an electrode was repeatedly formed in the length direction of the 1st above-mentioned electric insulating sheet to one side of a long flexible sheet original fabric And a second electrode group having a plurality of second electrodes formed on one surface of the long second electrical insulating sheet and arranged in a predetermined pattern on the second electrical insulating sheet. A second electrode sheet having a second electrode pattern that is repeatedly formed in the length direction of the electrically insulating sheet is composed of the second electrode of the second electrode group and the first electrode of the first electrode group. And laminated in a state of facing each other through And affixing step of forming the over bets,
A cutting step of cutting the laminated sheet between the first electrode groups adjacent to each other in the first electrode sheet and between the second electrode groups adjacent to each other in the second electrode sheet; It is characterized by including.

In the fall detection system of the present invention, the first electrode and the second electrode are a pair of electrode pairs, and a plurality of electrode pairs are formed as a pair of electrodes on both surfaces of a piezoelectric flexible sheet. The electrode and the second electrode are arranged in a state of being opposed to each other with the flexible sheet interposed therebetween, and are formed by a pair of electrode pairs and a flexible sheet portion existing between opposing surfaces of the electrodes constituting the electrode pair. A plurality of pressure sensors formed, a pressure sensor sheet,
The potential generated by the pressure sensor is received as an electrical signal, and it is determined whether the potential generated by each pressure sensor exceeds a preset potential threshold, and exceeds the preset potential threshold. After extracting the pressure-sensitive sensors that have generated potentials, whether or not the extracted pressure-sensitive sensors form a continuous pressure-sensitive sensor group in which the pressure-sensitive sensors are continuous with each other by a number equal to or greater than a preset number threshold. In the case where the continuous pressure-sensitive sensor group is formed, a fall detection unit for reporting the fall of the person to be observed is provided.

The fall detection system of the present invention includes a plurality of electrode pairs in which a first electrode and a second electrode are used as a pair of electrodes on both surfaces of a flexible sheet that is compressible and deformable so as to be restored in the thickness direction and has no piezoelectricity. The first electrode and the second electrode constituting the set of electrode pairs are disposed in a state of being opposed to each other with the flexible sheet interposed therebetween, and constitute a set of electrode pairs and the electrode pairs. A plurality of pressure-sensitive sensors formed by a flexible sheet portion existing between the opposing surfaces of the electrodes, and a pressure-sensitive sensor sheet,
The capacitance of each of the pressure sensors is received as an electrical signal, and it is determined whether or not the amount of change in capacitance of each pressure sensor exceeds a preset change amount threshold. After extracting the pressure-sensitive sensors in which a potential exceeding the threshold value is generated, a continuous pressure-sensitive sensor group is formed in which the pressure-sensitive sensors are continuous with each other by a number equal to or greater than a preset number threshold value. A fall detection unit for reporting the fall of the person being observed when the continuous pressure sensor group is formed.

  Since the fall detection system of the present invention has the configuration as described above, it can accurately detect that the person to be observed has fallen, and if the person to be observed falls, the fact is notified. In addition, it is possible to ensure prompt care for the subject.

  In the pressure-sensitive sensor sheet of the present invention, a plurality of pressure-sensitive sensors are formed by laminating and integrating a plurality of first electrodes and second electrodes on both surfaces of a flexible sheet. For example, when used in the above-described fall detection system, the load of the subject can be accurately detected by a pressure-sensitive sensor arranged at a predetermined position. The presence or absence of the subject's fall can be detected with high accuracy.

  Moreover, according to the method for producing a pressure-sensitive sensor sheet of the present invention, the pressure-sensitive sensor sheet can be produced continuously and easily.

It is the model top view which showed the pressure sensitive sensor sheet | seat. It is the schematic cross section which showed the pressure sensitive sensor sheet | seat. It is the schematic cross section which showed the other example which showed the pressure-sensitive sensor sheet | seat. It is the top view which showed the 1st electrode sheet (2nd electrode sheet). It is sectional drawing which showed the 1st electrode sheet (2nd electrode sheet). It is the schematic diagram which showed the manufacturing process of the pressure-sensitive sensor sheet. It is sectional drawing which showed the 1st electrode sheet (2nd electrode sheet) in the middle of manufacture of a pressure-sensitive sensor sheet. It is the schematic diagram which showed another example of the manufacturing process of a pressure-sensitive sensor sheet. It is the figure which showed the function structure of the fall detection system. It is the figure which showed the hardware constitutions of the fall detection system. It is the flowchart which showed operation | movement of the fall detection system. It is the schematic diagram which showed the specific point of the continuous pressure sensor group. It is the flowchart which showed operation | movement of the fall detection system.

  An example of the pressure-sensitive sensor sheet of the present invention will be described with reference to the drawings. As shown in FIGS. 1 and 2, the pressure-sensitive sensor sheet 1 is formed with a plurality of pressure-sensitive sensors B. The pressure sensitive sensor sheet 1 has a flexible sheet. The flexible sheet may be an electrically insulating sheet that can be compressed in the thickness direction, and may or may not have piezoelectricity. Piezoelectricity means that an electric force can be generated on the surface by applying an external force, that is, having a piezoelectric phenomenon. Examples of the flexible sheet having piezoelectricity include a foamed sheet charged by injecting a charge, a polyvinylidene fluoride sheet subjected to polarization treatment, and the like. As a flexible sheet having no piezoelectricity, no electric charge is injected (not charged) and it has electrical insulation. When stress is applied in the thickness direction, the sheet is compressed and deformed in the thickness direction. On the other hand, a sheet that can be restored to its original state when the stress in the thickness direction is removed. Such a flexible sheet is not particularly limited, and examples thereof include a rubber sheet, a thermoplastic elastomer sheet, a foamed sheet, and a sheet containing air inside.

  A plurality of first electrodes 12 are stacked and integrated on one surface of the flexible sheet 11 in a vertical and horizontal direction with a predetermined interval therebetween, and a plurality of second electrodes are formed on the other surface of the flexible sheet 11. The electrodes 13 are laminated and integrated by being arranged in the vertical and horizontal directions at a predetermined interval. Each of the first electrode 12 and the second electrode 13 is paired to constitute a pair of electrodes 10. The first electrode 12 and the second electrode 13 constituting the set of electrode pairs 10 are disposed so as to face each other with the flexible sheet 11 interposed therebetween. Therefore, the first electrode 12 and the second electrode 13 are arranged in the vertical and horizontal directions so as to face each other with the flexible sheet 11 interposed therebetween. 1 and 2 show the case where the first electrode 12 and the second electrode 13 are arranged vertically and horizontally with a predetermined interval therebetween, the present invention is not limited to this arrangement pattern.

  FIG. 2 shows the case where the areas of the first electrode 12 and the second electrode 13 viewed from the same plane are the same, but either one of the first electrode 12 and the second electrode 13 is more than the other electrode. Also, the area may be large, and when one electrode is projected in the thickness direction of the piezoelectric sheet 11, one electrode may include the other electrode.

  The first electrode 12 constituting the pair of electrodes 10, the second electrode 13 disposed opposite to the first electrode 12, the first electrode 12 facing each other, and the second electrode The pressure sensitive sensor B is formed by the flexible sheet portion 11a existing between the portions where the electrodes 13 overlap each other in the thickness direction of the flexible sheet. Therefore, when the pressure-sensitive sensor sheet 1 is viewed from the plane, the plurality of pressure-sensitive sensors B are formed in a state where they are arranged in the vertical and horizontal directions with a predetermined distance from each other.

  When a flexible sheet having piezoelectricity is used as the flexible sheet, the flexible sheet generates an electric charge on the surface when an external force is applied thereto, and the potential generated by the generation of the electric charge is used as a reference for the second electrode 13. Measurement can be performed through the first electrode 12 as an electrode. For example, when a pressing force is applied to the flexible sheet portion 11a of the pressure-sensitive sensor B due to the body weight of the person to be observed, the flexible sheet portion 11a is compressed by the pressing force, and an electric potential is generated in the flexible sheet portion 11a by the compression. The potential generated in the flexible sheet portion 11a increases as the pressing force received by the flexible sheet portion 11a increases. Further, in any pressure sensor B, the potential generated in the flexible sheet portion 11a does not affect other pressure sensors B adjacent to the pressure sensor B. Therefore, the potential generated in the arbitrary flexible sheet portion 11a by the pressing force is measured using the second electrode 13 as the reference electrode only through the first electrode 12 sandwiching the flexible sheet portion 11a. The potentials of the formed pressure sensor B are measured independently. When a flexible sheet having piezoelectricity is used as the flexible sheet, the power supply circuit for power feeding is not connected to the first electrode 12 and the second electrode 13, and electricity is supplied to the pressure sensor B. It has not been.

  When a flexible sheet having no piezoelectricity is used as the flexible sheet, in the pressure sensor B, the first electrode 12, the second electrode 13, and the first electrode 12 and the second electrode 13 are present. The flexible sheet portion 11a constitutes a capacitor. A direct current power source is connected between the first electrode 12 and the second electrode 13.

  When a pressing force is applied to the flexible sheet portion 11a of the pressure sensitive sensor B, the flexible sheet portion 11a is compressed by this pressing force, and the compression of the capacitor formed between the first electrode 12 and the second electrode 13 is compressed. The capacitance increases. The capacitance of the capacitor increases as the pressing force received by the flexible sheet portion 11a increases and the degree of compression of the flexible sheet portion 11a increases. Further, in any pressure-sensitive sensor B, the change in the capacitance of the capacitor does not affect the capacitance of another pressure-sensitive sensor B adjacent to the pressure-sensitive sensor B. Therefore, the change in the electrostatic capacitance generated in the arbitrary flexible sheet portion 11a due to the pressing force is measured only through the first electrode and the second electrode 13 sandwiching the flexible sheet portion 11a. The change in capacitance of the formed pressure sensitive sensor B is measured independently.

  As shown in FIG. 3, each of the first electrode 12 and the second electrode 13 in the pressure-sensitive sensor sheet 1 is preferably covered entirely with protective sheets 14 and 15.

As shown in FIG. 1, the plurality of pressure sensitive sensors B are arranged in a grid pattern at predetermined intervals in the vertical and horizontal directions. The plane area of each pressure sensor B is preferably 0.1 to ²⁰⁰ cm ² , and more preferably 10 to 150 cm ² , because it can detect with accuracy whether or not the person to be observed has fallen. The interval between the pressure-sensitive sensors B and B adjacent in the vertical and horizontal directions is preferably 1 to 100 mm because it can be detected with higher accuracy whether or not the person to be observed has fallen.

  Next, a method for manufacturing the pressure-sensitive sensor sheet will be described. As shown in FIGS. 4 and 5, a long first electrode sheet D in which a first electrode pattern 92 is formed on one surface of a long first electrically insulating sheet 91 is prepared. The first electrically insulating sheet 91 is not particularly limited as long as it can insulate electricity, and includes a synthetic resin sheet.

  The first electrode pattern 92 is configured such that the first electrode group 92 a is repeatedly formed at predetermined intervals in the length direction of the first electrical insulating sheet 91. The first electrode group 92a is integrated on one surface of the first electrically insulating sheet 91 via an adhesive layer 93 made of a known adhesive. The first electrode group 92a includes a plurality of first electrodes 12 arranged in a predetermined pattern. The arrangement pattern of the first electrodes 12 is not particularly limited, and examples thereof include a grid-like arrangement pattern arranged vertically and horizontally at predetermined intervals as shown in FIG. The first electrode 12 is composed of a conductive thin film having conductivity such as a metal foil or a metal thin film.

  Furthermore, the conductive wire 12a is electrically connected to each of the first electrodes 12. The conductive wires 12a connected to the first electrodes 12 are independent from each other and are not electrically connected to each other. Similar to the first electrode 12, the conductive wire 12a is composed of a conductive thin film having conductivity such as a metal foil, a metal thin film, or a coating film formed from a conductive paste.

  A pressure-sensitive adhesive layer 94 for integrating with the surface of the flexible sheet original is laminated and integrated on the outer surfaces of the first electrode 12 and the conductive wire 12a. For the pressure-sensitive adhesive layer 94, a known pressure-sensitive adhesive is used.

  Next, the manufacturing method of the 1st electrode sheet D is demonstrated. After a conductive thin film is laminated and integrated on one surface of the long first electrical insulating sheet 91 using a known adhesive, an adhesive layer is formed on the entire outer surface of the conductive thin film using a known adhesive. Form.

  Subsequently, the pressure-sensitive adhesive layer and the conductive thin film on the outer surface of the conductive thin film are cut into a predetermined pattern by a cutting blade from the pressure-sensitive adhesive layer side formed on the outer surface of the conductive thin film. The conductive thin film cut into a predetermined pattern becomes a plurality of first electrodes 12 and conductive wires 12a connected thereto, and an adhesive layer on the outer surface of the conductive thin film cut into a predetermined pattern An adhesive layer 94 on the first electrode 12 and the conductive wire 12a is formed.

  In addition, a long second electrode sheet E in which a second electrode pattern 96 is formed on one surface of the long second electrical insulating sheet 95 is prepared. The second electrically insulating sheet 95 is not particularly limited as long as it can insulate electricity, and includes a synthetic resin sheet.

  The second electrode pattern 96 is configured such that the second electrode group 96a is repeatedly formed at predetermined intervals in the length direction of the second electrically insulating sheet 95. The second electrode group 96a is integrated on one surface of the second electrically insulating sheet 95 via a pressure-sensitive adhesive layer 97 made of a known pressure-sensitive adhesive. In the second electrode group 96a, the plurality of second electrodes 13 are arranged in the same arrangement pattern as the arrangement pattern of the first electrode group 92a of the first electrode sheet D. The second electrode 13 is composed of a conductive thin film having conductivity such as a metal foil or a metal thin film.

  Further, a conductive line 13a is electrically connected to each of the second electrodes 13. The conductive wires 13a connected to the second electrodes 13 are independent from each other and are not electrically connected to each other. Similarly to the second electrode 13, the conductive wire 13a is composed of a conductive thin film having conductivity such as a metal foil, a metal thin film, or a coating film formed from a conductive paste.

  A pressure-sensitive adhesive layer 98 is integrated on the outer surfaces of the second electrode 13 and the conductive wire 13a so as to be integrated with the surface of the flexible sheet raw fabric. For the pressure-sensitive adhesive layer 98, a known pressure-sensitive adhesive is used.

  Next, the manufacturing method of the 2nd electrode sheet E is demonstrated. After a conductive thin film is laminated and integrated on one surface of the long second electrical insulating sheet 95 using a known adhesive, an adhesive layer is formed on the entire outer surface of the conductive thin film using a known adhesive. Form.

  Subsequently, the pressure-sensitive adhesive layer and the conductive thin film on the outer surface of the conductive thin film are cut into a predetermined pattern by a cutting blade from the pressure-sensitive adhesive layer side formed on the outer surface of the conductive thin film. The conductive thin film cut into a predetermined pattern becomes a plurality of second electrodes 13 and conductive wires 13a connected thereto, and an adhesive layer on the outer surface of the conductive thin film cut into a predetermined pattern An adhesive layer 98 on the second electrode 13 and the conductive wire 13a is formed.

  And as shown in FIG. 6, while winding the flexible sheet original fabric F of a winding state, the 1st electrode sheet D and the 2nd electrode sheet E of a winding state are unwound.

  On the first electrically insulating sheet 91 of the first electrode sheet D, the conductive thin film and the pressure-sensitive adhesive layer are also present in portions other than the conductive thin film and the pressure-sensitive adhesive layer constituting the first electrode 12 and the conductive wire 12a. Are stacked.

  Similarly, on the second electrically insulating sheet 95 of the second electrode sheet E, other than the conductive thin film portion constituting the second electrode 13 and the conductive wire 13a and the adhesive layer portion on the conductive thin film portion. The conductive thin film and the pressure-sensitive adhesive layer are also laminated on this part.

  Accordingly, after the conductive thin film portion constituting the first electrode 12 and the conductive wire 12a and the conductive thin film portion 10a and the pressure sensitive adhesive layer portion 10b other than the pressure sensitive adhesive layer on the conductive thin film portion are peeled and removed, The first electrode sheet D is laminated and integrated on one surface of the flexible sheet raw fabric F by the adhesive layer 94, and the first electrical insulating sheet 91 is laminated and integrated by the adhesive layer 93. In FIG. 7, the conductive thin film portion constituting the first electrode 12 and the conductive wire 12a and the conductive thin film portion 10a and the pressure sensitive adhesive layer portion 10b other than the pressure sensitive adhesive layer on the conductive thin film portion are separated. The cross section of the 1st electrode sheet D after removing is shown.

  Similarly, after peeling and removing the conductive thin film portion constituting the second electrode 13 and the conductive wire 13a and the conductive thin film portion 10c and the pressure sensitive adhesive layer portion 10d other than the pressure sensitive adhesive layer on the conductive thin film portion. The second electrode sheet E is laminated and integrated on the other surface of the flexible sheet raw fabric F by the adhesive layer 98, and the second electrically insulating sheet 95 is laminated and integrated by the adhesive layer 97. In FIG. 7, the conductive thin film portion constituting the second electrode 13 and the conductive wire 13a and the conductive thin film portion 10c and the pressure sensitive adhesive layer portion 10d other than the pressure sensitive adhesive layer on the conductive thin film portion are peeled off. The cross section of the 2nd electrode sheet E after removing is shown.

  At this time, in the first electrode 12 laminated and integrated on one surface of the flexible sheet original fabric F and the second electrode 13 laminated and integrated on the other surface of the flexible sheet original fabric F, one first electrode 12 and one are integrated. The first electrode sheet D is laminated and integrated on one surface of the flexible sheet original fabric F so that the second electrode 13 of the sheet is opposed to the thickness direction of the flexible sheet original fabric F to form a pair of electrodes. The second electrode sheet E is laminated and integrated on the other surface of the flexible sheet raw fabric F to form a laminated sheet G.

  When the area of one of the first electrode 12 of the first electrode sheet D and the second electrode 13 of the second electrode sheet E is made larger than the area of the other electrode, the flexible sheet raw fabric F When the first electrode sheet D and the second electrode sheet E are laminated on both surfaces of the first electrode 12 and the second electrode 13, the larger one of the first electrode 12 and the second electrode 13 facing each other with the flexible sheet raw fabric F interposed therebetween. The electrode may be disposed so as to include the electrode having the smaller area in the thickness direction of the flexible sheet original fabric F, and the first electrode 12 and the second electrode 13 are adjusted after strictly adjusting the positional relationship between the first electrode 12 and the second electrode 13. It is preferable that the sheet D and the second electrode sheet E are not disposed on the flexible sheet raw fabric F.

  Next, the laminated sheet G is cut between the first electrode groups 92a and 92a adjacent to each other in the first electrode sheet D and between the second electrode groups 96a and 96a adjacent to each other in the second electrode sheet E. A pressure sensor sheet is manufactured.

  In the above-described manufacturing method, the case where the first electrical insulating sheet 91 and the second electrical insulating sheet 95 are the protective sheets 14 and 15 for the first electrode 12 and the second electrode 13, respectively, has been described. As shown, the first electrode 12 is releasably laminated on the first electrically insulating sheet 91, the second electrode 13 is releasably laminated on the second electrically insulating sheet 95, and the first electrode sheet After laminating D and the second electrode sheet E on both sides of the flexible sheet raw fabric F, the first electrical insulating sheet 91 and the second electrical insulating sheet 95 may be peeled off and removed together with the adhesive layers 93 and 97. . In the pressure-sensitive sensor sheet thus manufactured, the first electrode 12 and the second electrode 13 are not covered with the protective sheets 14 and 15.

  Next, an example of the fall detection system using the pressure-sensitive sensor sheet will be described with reference to the drawings. First, a fall detection system using a pressure-sensitive sensor sheet in which a flexible sheet having piezoelectricity is used as the flexible sheet will be described.

  According to the fall detection system A of the present invention, the observer falls down based on the pressure-sensitive sensor sheet 1 in which a plurality of pressure-sensitive sensors B are formed and the potential generated by the pressure-sensitive sensor B of the pressure-sensitive sensor sheet 1. And a fall detection unit 2 that determines whether or not the state has been achieved.

  The fall detection system A has a pressure-sensitive sensor sheet 1 on which a plurality of pressure-sensitive sensors B are formed as shown in FIGS. 1 and 2. As described above, the potentials of the pressure sensor B formed on the pressure sensor sheet 1 are independently measured, and are observed from the distribution state of the pressure sensors that have generated a potential exceeding a preset potential threshold. It is determined whether the person has fallen.

  The fall detection system A functionally has a pressure sensor sheet 1 on which a plurality of pressure sensors B are formed, a fall detection unit 2 and a storage unit 3 as shown in FIG. Yes. Further, the fall detection system A physically has a pressure-sensitive sensor sheet 1, a CPU (Central Processing Unit) 41, a ROM (Read Only Memory) 42, and a RAM (Random Access) as shown in FIG. Memory) 43, auxiliary storage device 44 such as SSD (Solid State Drive) and HDD (Hard Disk Drive), measurement module 45, and output module 46 such as a display, a speaker, and a portable terminal device. The pressure-sensitive sensor sheet 1, ROM 42, RAM 43, auxiliary storage device 44, measurement module 45, and output module 46 are electrically connected to the CPU 41 so that they can communicate with each other. As the measurement module 45, a known electrometer can be used.

  The fall detection system A described with reference to FIG. 9 operates the measurement module 45 and the output module 46 under the control of the CPU 41 by reading a predetermined program on the CPU 41 and the RAM 43 shown in FIG. And by reading and writing data in the auxiliary storage device 44.

  The fall detection unit 2 of the fall detection system A includes a CPU 41 and exhibits a predetermined function by executing a program stored in the ROM 42 or the like.

  The first electrode and the second electrode of each pressure sensor B of the pressure sensor sheet 1 are independently electrically connected to the measurement module 45 via conductive wires, and the second electrode is used as a reference potential. The potential of one electrode can be measured by the measurement module 45.

  The operation of the fall detection system A will be described with reference to FIG. The pressure-sensitive sensor sheet 1 is disposed on a floor surface in a room such as a hospital room or a living room or under a floor material. The CPU 41 constantly measures the potentials of all the pressure sensors B of the pressure sensor sheet 1 by the measurement module 45 in a state of being independent from each other (step 1 (S1)).

The pressure-sensitive sensors B of the pressure-sensitive sensor sheet 1 are arranged in a grid pattern vertically and horizontally. In FIG. 1, the pressure-sensitive sensors arranged in the uppermost row are sequentially arranged as B ₁₁ , B _{12. 1n} , pressure sensors arranged in the next row (second row) are sequentially designated as B ₂₁ , B ₂₂ ... B _2n, and pressure sensors arranged in the m-th row are sequentially _designated as B _m1 , B Each pressure-sensitive sensor is distinguished by _m2 ... _Bmn .

  When a caregiver or an observer is placed on the pressure-sensitive sensor sheet 1, the pressure-sensitive sensor B on which a person is placed among the pressure-sensitive sensors B of the pressure-sensitive sensor sheet 1 is piezoelectric depending on the weight of the person. The sheet is compressed and an electric potential is generated in the piezoelectric sheet. The potential generated in each pressure sensor B is measured by the measurement module 45, and each measured potential of the pressure sensor B is converted into a digital signal by a known method, and then independently sent to the CPU 41. It is transmitted as a signal.

  The storage unit 3 including the RAM 43, the auxiliary storage device 44, and the like has a potential threshold value that serves as a reference for determining whether or not the potential generated by the pressure sensor is due to the fall of the observer. Pre-stored for each observer. The potential threshold is set based on the weight and height of the person to be observed. The potential threshold may be set with reference to the potential generated by the pressure sensor when the person to be observed lies down. Therefore, when the potential threshold is set with the subject being an adult male, it may not be determined that the subject has fallen in the operation described below when a child or an adult female becomes the subject. The potential threshold needs to be set in consideration of the weight and height of the subject.

  The CPU 41 detects whether any potential is generated in the first electrode 23 with the second electrode 13 as a reference electrode in any of the pressure sensitive sensors B (step 2 (S2)). When no pressure is generated in all the pressure sensors B, the CPU 41 continues to detect the potential of each pressure sensor B by the measurement module 45.

  On the other hand, when the generation of a potential is confirmed in at least one pressure sensor B by the CPU 41, the potential measured in the pressure sensor B is compared with the potential threshold value stored in the storage unit 3, It is determined for each pressure sensor B whether or not the potential generated by the pressure sensor B exceeds the potential threshold (step 3 (S3)).

  When the CPU 41 determines that there is no pressure sensor B that has generated a potential exceeding the potential threshold, the potential of each pressure sensor B of the pressure sensor sheet 1 is continuously measured by the measurement module 45. The

  On the other hand, if the CPU 41 determines that there is a pressure sensor B that has generated a potential that exceeds the potential threshold, the CPU 41 extracts the pressure sensor B that has generated a potential that exceeds the potential threshold (step 4). (S4)).

Next, in the extracted pressure sensor B, the CPU 41 determines whether or not the pressure sensor B continuously forms a continuous pressure sensor group with a number equal to or greater than a preset number threshold. (Step 5 (S5)). In the storage unit 3, a number threshold for determining whether or not the potential generated by the pressure sensor is due to the fall of the person to be observed is stored in advance for each person to be observed. The pressure sensors that are present in succession to each other means that when any two pressure sensors are extracted and there is no other pressure sensor between the two pressure sensors, these pressure sensors are detected. The sensors shall be continuous with each other. For example, in FIG. 1, B ₁₂ and B ₂₂ , B ₂₂ and B ₂₃ , and B ₂₂ and B ₃₃ are continuous pressure sensors.

  Then, it is determined in the following manner whether or not the pressure-sensitive sensors B form a continuous pressure-sensitive sensor group with a number equal to or greater than a preset number threshold. First, an arbitrary pressure sensor is defined as a central pressure sensor. A pressure sensor having a continuous relationship with the central pressure sensor is specified. Next, a pressure sensor having a continuous relationship with the central pressure sensor is newly set as the central pressure sensor, and a pressure sensor having a continuous relationship with the central pressure sensor is specified. Furthermore, a pressure sensor having a continuous relationship with the new central pressure sensor is set as a new central pressure sensor, and a pressure sensor having a continuous relationship with the central pressure sensor is specified. By repeating this procedure, when the total number of pressure sensors that are all central pressure sensors and the pressure sensors in a continuous relationship with these pressure sensors is equal to or greater than the number threshold, all of these sensors are detected. It is assumed that the pressure sensors form a continuous pressure sensor group.

For example, in FIG. 12, the pressure sensor B that has generated a potential that exceeds the potential threshold is indicated by a solid line, and the pressure sensor B that has generated a potential that is equal to or lower than the potential threshold is indicated by a dotted line. In FIG. 12, the figure drawn in an ellipse is a diagram showing an example of a state in which the person to be observed falls. In the following description, the upper left pressure sensor of FIG. 12 and B _11, is set to four and the number threshold. In the pressure sensor shown in solid lines, when the pressure sensitive sensor B ₂₂ centered pressure sensor, pressure sensor B _23, B ₃₂ and B ₃₃ are in a continuous relationship to the pressure sensitive sensor B ₂₂ . Next, when the pressure sensor B ₃₃ having a continuous relationship with the pressure sensor B ₂₂ is the central pressure sensor, the pressure sensors B ₂₄ , B ₃₄ , and B ₄₄ are connected to the pressure sensor B _33. Are in a continuous relationship. Next, when the pressure sensor B ₂₄ is a central pressure sensor, the pressure sensor B ₂₅ has a continuous relationship with the pressure sensor B ₂₄ , and the pressure sensor B ₂₅ is a central pressure sensor. When the pressure sensor B ₂₆ is in a continuous relationship with the pressure sensor B ₂₅ . Further, when the pressure sensor B ₄₄ is a central pressure sensor, the pressure sensors B ₄₅ , B ₅₃ , and B ₅₄ are in a continuous relationship with the pressure sensor B ₄₄ . Next, when the pressure sensor B ₅₃ is a central pressure sensor, the pressure sensors B ₅₂ and B ₆₂ have a continuous relationship with the pressure sensor B ₅₃ . Finally, when the pressure sensor B ₅₂ is a central pressure sensor, the pressure sensors B ₅₁ and B ₆₁ are in a continuous relationship with the pressure sensor B ₅₂ . The total number of pressure sensors B _{22 to} B ₂₆ , B _{32 to} B ₃₄ , B ₄₄ , B ₄₅ , B _{51 to} B ₅₄ , B ₆₁ and B ₆₂ is 4 (number threshold or more). Thus, a continuous pressure-sensitive sensor group is formed. In the above description, the pressure sensors B that are apparently continuous with each other are not redundantly described. On the other hand, if the number of pressure sensors B that are in a continuous relationship with each other in the same manner as described above is less than the number threshold value (here, 3 or less), a continuous pressure sensor group is not formed.

  As described above, the CPU 41 determines whether or not there is a continuous pressure-sensitive sensor group. When the person to be observed falls on the pressure-sensitive sensor sheet 1, the plurality of pressure-sensitive sensors B of the pressure-sensitive sensor sheet 1 receive a pressing force by the person to be fallen. At this time, the pressure sensor B is pressed by the fallen subject with a continuous pressing surface of a certain level or more. Therefore, the CPU 41 determines whether or not the subject has fallen by determining whether or not the continuous pressure-sensitive sensor group exists in the manner described above.

  The number threshold of the pressure sensor B includes one continuous pressing area where the observer presses the pressure sensor when the observer falls on the pressure sensor sheet 1, and one pressure sensor. Is determined based on the planar area (planar area of the first electrode). “One continuous pressing area” is set for each person to be observed, and when the person to be observed lies down on the pressure-sensitive sensor sheet 1, the legs of the person to be observed press the pressure-sensitive sensor sheet 1. It suffices to set the area to be used as a guide. This is because the observer's leg presses the pressure-sensitive sensor sheet 1 regardless of whether the person falls down on the pressure-sensitive sensor sheet 1 and is in a lying state in a state of lying down, lying down or lying up. This is because the area to be changed does not change so much. Since the “one continuous pressing area” can detect with high accuracy whether or not the subject has fallen, it is preferable to make the area larger than the area of the sole of the foot of the subject. .

  When the presence of the continuous pressure sensor group is confirmed by the CPU 41, after a warning signal indicating that the person to be observed has fallen is output by the CPU 41 to the output module 46 such as a display, a speaker, or a portable terminal device (step 6 (S6)), the process returns to step 1. By the output of the warning signal from the output module 46, the caregiver can recognize that the person to be observed has fallen and can immediately care for the person to be observed.

  On the other hand, when the presence of the continuous pressure sensor group is not confirmed by the CPU 41, it is determined that it is not caused by the fall of the person to be observed, and the pressure sensor sheet 1 has some sort of person or object. A placement signal indicating that the object is on is output to the output module 46 by the CPU 41 and reported to the caregiver (step 7 (S7)), and the caregiver confirms the state of the subject as necessary. You can take necessary actions. Then, it returns to step 1.

  Next, a fall detection system using a pressure-sensitive sensor sheet in which a flexible sheet having no piezoelectricity is used as the flexible sheet will be described. In the fall detection system, instead of the flexible sheet having piezoelectricity, a flexible sheet having no piezoelectricity was used as the flexible sheet, and a DC power source was connected between the first electrode 12 and the second electrode 13. As a measurement module, for example, an LCR meter is used as an apparatus for measuring the capacitance of a capacitor formed between the first electrode 13 and the second electrode 13, except that an LCR meter is used. Since the configuration is the same, the description thereof is omitted.

  The operation of the fall detection system A will be described with reference to FIG. The pressure-sensitive sensor sheet 1 is disposed on a floor surface in a room such as a hospital room or a living room or under a floor material. The CPU 41 allows the capacitances of the capacitors (hereinafter sometimes simply referred to as “capacitors”) constituted by the first electrodes 12 and the second electrodes 13 of all the pressure sensitive sensors B of the pressure sensitive sensor sheet 1 to be independent of each other. In this state, the measurement is always performed by the measurement module 45 (step 8 (S8)).

The pressure-sensitive sensors B of the pressure-sensitive sensor sheet 1 are arranged in a grid pattern vertically and horizontally. In FIG. 1, the pressure-sensitive sensors arranged in the uppermost row are sequentially arranged as B ₁₁ , B _{12. 1n} , pressure sensors arranged in the next row (second row) are sequentially designated as B ₂₁ , B ₂₂ ... B _2n, and pressure sensors arranged in the m-th row are sequentially _designated as B _m1 , B Each pressure-sensitive sensor is distinguished by _m2 ... _Bmn .

  When a caregiver or an observer is placed on the pressure-sensitive sensor sheet 1, the pressure-sensitive sensor B on which the person is placed among the pressure-sensitive sensors B of the pressure-sensitive sensor sheet 1 is flexible depending on the weight of the person. The sheet is compressed in the thickness direction so as to be elastically restored, and the capacitance of the capacitor formed between the first electrode 12 and the second electrode 13 increases. The capacitance of the capacitor formed by each pressure sensor B is measured by the measurement module 45, and the measured capacitance of the pressure sensor B is converted into a digital signal by a known method. Then, it is independently transmitted as an electric signal to the CPU 41.

In the storage unit 3 including the RAM 43 and the auxiliary storage device 44, it is determined whether or not the amount of change in the capacitance of the capacitor formed by the pressure sensor B is due to the fall of the observer. A change amount threshold value used as a reference for determination is stored in advance for each person to be observed, and a capacitor formed by the pressure sensor B measured in a state where no object is placed on the pressure sensor. Capacitance (capacitance reference value C ₀ ) is stored in advance. The change amount threshold is set based on the weight and height of the person to be observed. The change amount threshold value may be set using as a guide the difference between the capacitance of the capacitor formed by the pressure-sensitive sensor when the subject is lying down and the capacitance reference value C ₀ . Therefore, when the change amount threshold is set with the observed person as an adult male, it may not be determined that the observed person has fallen in the operation described later when a child or an adult female becomes the observed person. The capacitance threshold value needs to be set in consideration of the weight and height of the subject. The capacitance reference value C ₀ is obtained by measuring in advance the capacitance of a capacitor formed by a pressure sensor in a state where no object is placed on the pressure sensor B. The reference value C ₀ may be set.

The CPU 41 calculates the change amount C _{1 of the} capacitance C of the capacitor measured in each pressure sensor B with respect to the capacitance reference value C _{0, and} the change amount of the capacitance calculated in each pressure sensor B. It is determined whether or not there is a C ₁ exceeding a predetermined change amount threshold stored in the storage unit 3 (step 9 (S9)). When the change amount C _{1 of the} capacitance calculated in all the pressure sensors B is equal to or less than the capacitance threshold value, the capacitance C of the capacitor formed in each pressure sensor B by the CPU 41 is measured. Continue to be measured by module 45.

On the other hand, feeling the CPU 41, the pressure sensor B the variation C ₁ exceeding the amount of change threshold has occurred when it is determined that there is the CPU 41, the change amount C ₁ which exceeds the variation threshold has occurred The pressure sensor B is extracted (step 10 (S10)).

  Next, in the pressure sensor B extracted by the CPU 41, whether or not the pressure sensor B continuously forms a continuous pressure sensor group with a number equal to or greater than a preset number threshold is described above. A similar determination is made (step 11 (S11)).

  As described above, the CPU 41 determines whether or not there is a continuous pressure-sensitive sensor group. When the person to be observed falls on the pressure-sensitive sensor sheet 1, the plurality of pressure-sensitive sensors B of the pressure-sensitive sensor sheet 1 receive a pressing force by the person to be fallen. At this time, the pressure sensor B is pressed by the fallen subject with a continuous pressing surface of a certain level or more. Therefore, the CPU 41 determines whether or not the subject has fallen by determining whether or not the continuous pressure-sensitive sensor group exists in the manner described above. The number threshold of the pressure sensitive sensor B is determined in the same manner as described above.

  When the presence of the continuous pressure sensor group is confirmed by the CPU 41, a warning signal indicating that the person to be observed has fallen is output by the CPU 41 to the output module 46 such as a display, a speaker, or a portable terminal device (step 12). (S12)). By the output of the warning signal from the output module 46, the caregiver can recognize that the person to be observed has fallen and can immediately care for the person to be observed. Thereafter, the process returns to step 8.

  On the other hand, when the presence of the continuous pressure sensor group is not confirmed by the CPU 41, it is determined that it is not caused by the fall of the person to be observed, and the pressure sensor sheet 1 has some sort of person or object. A placement signal that means that an object is on is output to the output module 46 by the CPU 41 and reported to the caregiver, and the caregiver checks the state of the person to be observed as necessary, etc. (Step 13 (S13)). Thereafter, the process returns to step 8.

1 Pressure-sensitive sensor sheet
11 Piezoelectric sheet
11a Flexible sheet part
12 First electrode
12a Conductive wire
13 Second electrode
13a Conductive wire
14,15 Protection sheet
91 First electrical insulation sheet
92 First electrode pattern
92a First electrode group
93 Adhesive layer
94 Adhesive layer
95 Second electrical insulation sheet
96 Second electrode pattern
96a Second electrode group
97 Adhesive layer
98 Adhesive layer 2 Fall detection part A Fall detection system B Pressure sensor

Claims (7)

  The first electrode and the second electrode, which form a pair of electrode pairs on both sides of the flexible sheet, include a plurality of electrode pairs each having the first electrode and the second electrode as a pair of electrodes. A plurality of pressure-sensitive sensors formed by a pair of electrode pairs and a flexible sheet portion existing between opposing surfaces of the electrodes constituting the electrode pairs are formed in a state of being opposed to each other. A pressure-sensitive sensor sheet. A first electrode group including a long first electric insulating sheet and a plurality of first electrodes formed on one surface of the first electric insulating sheet and arranged in a predetermined pattern is the first electric insulating sheet. The first electrode sheet having the first electrode pattern formed repeatedly in the length direction of the insulating sheet is adhered to one surface of the long flexible sheet raw material, and the long second electrical insulating sheet; A second electrode group having a plurality of second electrodes formed on one surface of the second electrically insulating sheet and arranged in a predetermined pattern is repeatedly formed in the length direction of the second electrically insulating sheet. The second electrode sheet having the second electrode pattern is pasted so that the second electrode of the second electrode group and the first electrode of the first electrode group face each other through the flexible sheet original fabric. An attaching step for forming a laminated sheet;
A cutting step of cutting the laminated sheet between the first electrode groups adjacent to each other in the first electrode sheet and between the second electrode groups adjacent to each other in the second electrode sheet; A method for producing a pressure-sensitive sensor sheet, comprising:   The conductive lines are electrically connected to each of the first electrodes of the first electrode sheet, and the conductive lines are electrically independent of each of the second electrodes of the second electrode sheet. It is connected, The manufacturing method of the pressure-sensitive sensor sheet | seat of Claim 2 characterized by the above-mentioned.   3. The method according to claim 2, wherein when one of the first electrode and the second electrode is projected in the thickness direction of the flexible sheet material, one electrode includes the other electrode. Item 4. A method for producing a pressure-sensitive sensor sheet according to Item 3. The first electrode and the second electrode, wherein a plurality of electrode pairs each having the first electrode and the second electrode as a set of electrode pairs form a pair of electrode pairs on both sides of the flexible sheet having piezoelectricity, A plurality of pressure-sensitive sensors arranged in a state of being opposed to each other with the flexible sheet interposed therebetween, and formed by a pair of electrode pairs and a flexible sheet portion existing between opposing surfaces of the electrodes constituting the electrode pairs. A formed pressure-sensitive sensor sheet;
The potential generated by the pressure sensor is received as an electrical signal, and it is determined whether the potential generated by each pressure sensor exceeds a preset potential threshold, and exceeds the preset potential threshold. After extracting the pressure-sensitive sensors that have generated potentials, whether or not the extracted pressure-sensitive sensors form a continuous pressure-sensitive sensor group in which the pressure-sensitive sensors are continuous with each other by a number equal to or greater than a preset number threshold. A fall detection system comprising: a fall detection unit that determines whether or not the continuous pressure-sensitive sensor group is formed and reports the fall of the person being observed. A plurality of electrode pairs in which the first electrode and the second electrode are set as one electrode pair are arranged on both surfaces of a flexible sheet that is compressible and deformable so as to be restored in the thickness direction and does not have piezoelectricity. The first electrode and the second electrode are arranged in a state of being opposed to each other with the flexible sheet interposed therebetween, and exist between a pair of electrode pairs and the opposing surfaces of the electrodes constituting the electrode pair. A plurality of pressure-sensitive sensors formed by the flexible sheet portion, and a pressure-sensitive sensor sheet formed;
The capacitance of each of the pressure sensors is received as an electrical signal, and it is determined whether or not the amount of change in capacitance of each pressure sensor exceeds a preset change amount threshold. After extracting the pressure-sensitive sensors in which a potential exceeding the threshold value is generated, a continuous pressure-sensitive sensor group is formed in which the pressure-sensitive sensors are continuous with each other by a number equal to or greater than a preset number threshold value. A fall detection system comprising: a fall detection unit that determines whether or not the continuous pressure-sensitive sensor group is formed and reports the fall of the observer. The fall detection system according to claim 5 or 6, wherein the pressure sensitive sensors are arranged in a grid pattern at predetermined intervals in the vertical and horizontal directions.

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