JP2014062766A - Detection system, and detection sheet - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a detection system and detection sheet capable of being operated at a low cost.SOLUTION: A detection system 1 comprises: a detection device 10 having a loop coil 22; and a detector 40 for detecting variation in capacity of the loop coil 22. The detection device 10 comprises: a loop coil sheet 20 having the loop coil 22; and a detection sheet 30 having an adhesion layer 33 that is mounted on an adherend 2 and peelably adheres to the loop coil sheet 20, and a detection layer 32 for varying the impedance of the loop coil 22 by reacting with gas generated from the adherend 2. The detector 40 is bonded to the loop coil 22 by electromagnetic induction and detects the variation in impedance of the loop coil 22.

Description

  The present invention relates to a detection system and a detection sheet for detecting a change in the state of a subject.

  Conventionally, there has been an analysis system that analyzes a state of a container by attaching a detection device in which an RFID tag and a sensor as a detection layer are integrated to a container that is an adherend (for example, Patent Document 1). This analysis system utilizes the fact that the sensor chemically changes due to the gas generated by the container, and the electrical characteristics change.

Special table 2010-510523

Conventionally, after use, the sensing device, i.e. the chemically altered sensor and the RFID tag integral with it, must be discarded. Since this RFID tag forms a loop antenna by etching or the like, it is expensive. For this reason, the operation cost of the conventional analysis system is high.
An object of the present invention is to provide a detection system and a detection sheet that can be operated at low cost.

The present invention solves the problems by the following means. In addition, in order to make an understanding easy, although the code | symbol corresponding to embodiment of this invention is attached | subjected and demonstrated, it is not limited to this. In addition, the configuration described with reference numerals may be improved as appropriate, or at least a part thereof may be replaced with another configuration.
The first invention includes a detection device (10, 210, 310, 410, 410A, 410B, 510) having a loop coil (22) and a detector (40) for detecting a change in impedance of the loop coil. The detection system includes a loop coil sheet (20, 420) having the loop coil and an adherend (2), and is detachably bonded to the loop coil sheet. Adhesion layer (33, 333, 433, 433B) and detection layer (32, 232, 332, 432, 432A, 432B, 532) for changing the impedance of the loop coil in response to the gas generated from the adherend A detection sheet (30, 230, 330, 430, 430A, 430B, 530) having Le and coupled by electromagnetic induction, detecting a change in the impedance of the loop coil, a detection system characterized.
The second invention is a detection system according to the detection system of the first invention, wherein the detection layer (232, 432A) has adhesiveness and also serves as the adhesive layer. .
-3rd invention WHEREIN: When the surface of the said detection sheet | seat (420, 420B) is seen from the normal line direction in the detection system of 1st or 2nd invention, the said detection layer (332,432B) is the said A detection system characterized in that the loop coil sheet (20) is disposed in a region covering the loop coil (22), and the adhesive layers (333, 433B) are disposed in a region other than the detection layer. is there.
The fourth invention is the detection system according to any one of the first to third inventions, wherein the loop coil (22) of the loop coil sheet (20) is an open circuit, and the first is at the end thereof. The detection layer (432, 432A, 432B) includes a connection portion (426a, 426b) and is provided at an end of the detection layer loop coil (435) that is an open circuit and the detection layer loop coil. A second connection part (436a, 436b) electrically connected to the connection part, and the loop coil and the detection layer loop coil of the loop coil are connected by the first connection part and the second connection part. The detection system is characterized by integrally forming one loop coil.
The fifth invention is the detection system according to any one of the first to third inventions, wherein the detection layer (532) is coupled to the loop coil by an electromagnetic induction method. ).
The sixth invention is the detection system according to any one of the first to fifth inventions, wherein the loop coil sheet (20, 420) includes an IC chip (23) connected to the loop coil, and the detection The detector (40) is a detection system characterized in that it communicates with the IC chip by being coupled to the loop coil by electromagnetic induction.

The seventh invention is a detection sheet (30, 230, 330, 430, 430A, 430B, 530) to which a loop coil sheet (20, 420) having a loop coil (22) is detachably mounted, An adhesive layer (33, 333, 433, 433B) attached to the adherend (2) and detachably bonded to the loop coil sheet, and the impedance of the loop coil in response to the gas generated from the adherend Detection layer (32, 232, 332, 432, 432A, 432B, 532), and the detector (40) is electromagnetically coupled to the loop coil while the loop coil sheet is mounted on the detection sheet. It is a detection sheet characterized in that a change in impedance of the loop coil can be detected by coupling by induction.
The eighth invention is the detection sheet according to the seventh invention, wherein the detection layer (232, 432A) has adhesiveness and also serves as the adhesive layer. .
-9th invention WHEREIN: When the surface of this detection sheet | seat (430, 420B) is seen from a normal line direction in the detection sheet | seat of 7th or 8th invention, the said detection layer is the said loop coil sheet | seat (20 ) In the region covering the loop coil (22), and the adhesive layer (333, 433B) is disposed in a region other than the detection layer.
The tenth aspect of the invention is the detection sheet according to any one of the seventh to ninth aspects, wherein the loop coil (22) of the loop coil sheet (20) is an open circuit, and the first end of the loop coil (22) The detection layer (432, 432A, 432B) includes a connection portion (426a, 426b) and is provided at an end of the detection layer loop coil (435) that is an open circuit and the detection layer loop coil. A second connection part (436a, 436b) electrically connected to the connection part, and the loop coil and the detection layer loop coil of the loop coil are connected by the first connection part and the second connection part. The detection sheet is characterized by integrally forming one loop coil.
The eleventh invention is the detection sheet according to any one of the seventh to ninth inventions, wherein the detection layer (532) is coupled to the loop coil by an electromagnetic induction method. It is a detection sheet | seat characterized by providing.

The twelfth invention is a detection system (601) comprising a detection device (610, 610A, 610B) having a loop coil (622) and a detector (640) for detecting a change in impedance of the loop coil. The detection device includes a loop coil sheet (620) having the loop coil (622) and an adhesive layer (633, 633B) that is attached to the adherend (2) and is detachably bonded to the loop coil sheet. And a detection sheet (630, 630A, 630B) having a detection layer (632, 632A, 632B) that changes the impedance of the loop coil in response to a gas generated from the adherend, , Electrically connected to the loop coil by wire, and detecting a change in impedance of the loop coil; A detection system comprising.
The thirteenth invention is the detection system according to the twelfth invention, wherein the detection layer (632A) has adhesiveness and also serves as the adhesive layer.
-14th invention WHEREIN: When the surface of the said detection sheet | seat (610B) is seen from a normal line direction in the detection system of 12th or 13th invention, the said detection layer (632B) is the said loop coil sheet | seat ( 620) is arranged in a region covering the loop coil (622), and the adhesive layer (633B) is arranged in a region other than the detection layer.

The fifteenth aspect of the invention is a detection sheet (630, 630A, 630B) on which a loop coil sheet (620) having a loop coil (622) is detachably mounted, and is mounted on an adherend (2), An adhesive layer (633, 633B) that releasably adheres to the loop coil sheet, and a detection layer (632, 632A, 632B) that changes the impedance of the loop coil in response to a gas generated from the adherend. In a state where the loop coil sheet is mounted on the detection sheet, a detector (640) is electrically connected to the loop coil by a wire, and a change in impedance of the loop coil can be detected. The detection sheet characterized by the above.
The sixteenth invention is the detection sheet according to the fifteenth invention, wherein the detection layer (632A) has adhesiveness and also serves as the adhesive layer.
The seventeenth aspect of the present invention is the detection sheet of the fifteenth or sixteenth aspect, wherein when the surface of the detection sheet is viewed from the normal direction, the detection layer (632B) is formed of the loop coil sheet (620). The detection sheet is disposed in a region covering the loop coil (622), and the adhesive layer (633B) is disposed in a region other than the detection layer.

  According to the present invention, it is possible to provide a detection system and a detection sheet that can be operated at low cost.

It is a figure explaining the composition of detection system 1 of a 1st embodiment. It is sectional drawing of the detection apparatus 10 (the loop coil sheet | seat 20, the detection sheet | seat 30) of 1st Embodiment. It is a top view (figure seen from the upper side Z2 shown in FIG. 2) of the loop coil sheet | seat 20 of 1st Embodiment. It is sectional drawing of the detection apparatus 210 (the loop coil sheet | seat 20, the detection sheet 230) of 2nd Embodiment. It is sectional drawing of the detection apparatus 310 (the loop coil sheet | seat 20, the detection sheet 330) of 3rd Embodiment. It is a top view of detection device 310 (loop coil sheet 20, detection sheet 330) of a 3rd embodiment. It is sectional drawing of the detection apparatus 410 (Loop coil sheet | seat 420, the detection sheet | seat 430) of 4th Embodiment. It is a figure explaining the positional relationship of the loop coil 22 of the loop coil sheet | seat 420 of 4th Embodiment, and the loop coil 435 of the detection layer 432. FIG. It is sectional drawing of 410 A of detection apparatuses (loop coil sheet | seat 420, detection sheet | seat 430A) of 4th Embodiment. It is sectional drawing of the detection apparatus 410B (loop coil sheet | seat 420, the detection sheet | seat 430B) of 4th Embodiment. It is a figure explaining the positional relationship of the loop coil 22 of the loop coil sheet | seat 20 of 5th Embodiment, and the loop coil 535 of the detection sheet | seat 530. FIG. It is a figure explaining the structure of the detection system 601 of 6th Embodiment. It is sectional drawing of the detection apparatus 610 (Loop coil sheet | seat 620, the detection sheet | seat 630) of 6th Embodiment. It is sectional drawing of detection apparatus 610A (loop coil sheet 620, detection sheet 630A) of 6th Embodiment. It is sectional drawing of the detection apparatus 610B (loop coil sheet | seat 620, the detection sheet | seat 630B) of 6th Embodiment. It is a figure explaining the structure of the detection system 701 of 7th Embodiment. It is sectional drawing of the detection apparatus 710 of 7th Embodiment, and a bottom view (figure seen from the lower side Z1).

(First embodiment)
Hereinafter, a first embodiment of the present invention will be described with reference to the drawings and the like.
FIG. 1 is a diagram illustrating the configuration of the detection system 1 according to the first embodiment.
The detection system 1 includes a detection device 10 and a detector 40, and is a system that analyzes the situation of the adherend 2 using these. The detection device 10 reacts to the gas generated by the adherend 2 according to its state, and the detector 40 measures the degree of this reaction of the detection device 10. Thereby, the detection system 1 can analyze the state of the adherend 2.
The adherend 2 refers to an object to which the detection device 10 is attached at the time of detection, and may be composed of two or more objects. For example, when the diaper 2a equipped with the detection device 10 is further worn on the subject 2b, which is a human body, the concept that both the diaper 2a and the subject 2b are the adherend 2 is the concept.

FIG. 2 is a cross-sectional view of the detection device 10 (the loop coil sheet 20 and the detection sheet 30) according to the first embodiment.
FIG. 3 is a plan view of the loop coil sheet 20 of the first embodiment (viewed from the upper side Z2 shown in FIG. 2).
As shown in FIG. 2, the detection device 10 includes a loop coil sheet 20 and a detection sheet 30.
The loop coil sheet 20 is an RFID tag.
As shown in FIGS. 2 and 3, the loop coil sheet 20 includes a base material 21, a loop coil 22, and an IC chip 23.
The loop coil 22 functions as a loop antenna. The loop coil sheet 20 is provided on the base material 21 by etching or the like.
The IC chip 23 is connected to the loop coil 22. The IC chip 23 includes a control unit (not shown) including a CPU and the like, a storage device (not shown) that stores identification information of the loop coil sheet 20, and the like. The control unit controls communication with the detector 40.

As shown in FIG. 2, the detection sheet 30 is a sheet attached to the adherend 2.
The detection sheet 30 includes a base material 31, a detection layer 32, an adhesive layer 33, and a release sheet 34. The detection layer 32, the adhesive layer 33, and the release sheet 34 are laminated on the lower surface of the base material 31 in this order.
The base material 31 is a resin sheet such as PET. The base material 31 suppresses penetration of moisture or the like into the detection layer 32.
The base material 31 has a plurality of vent holes 31a.
The vent hole 31 a is a through hole that allows the gas generated from the adherend 2 to vent through the detection layer 32. FIG. 2A shows a state before the loop coil sheet 20 is bonded to the detection sheet 30, and FIG. 2B shows a state where the loop coil sheet 20 is bonded to the detection sheet 30 and laminated. In the present embodiment, the gas is a concept including water vapor.

The detection layer 32 changes the impedance of the loop coil 22 in response to the gas generated from the adherend 2. For the detection layer 32, for example, a member similar to the sensor disclosed in JP-T-2010-510523 is used.
The detection layer 32 has a property that the degree of impedance change of the loop coil 22 varies depending on the type of gas. For this reason, as for the characteristic of the resonance frequency of the loop coil 22, the decrease of the peak value, the deviation of the frequency of the peak value, and the like differ depending on the type of gas. Such a decrease in the peak value, a shift in the frequency of the peak value, and the like are appropriately referred to as a characteristic change in the resonance frequency. In particular, since the change in impedance is significantly different between water vapor and other gases (such as hydrogen sulfide), the characteristic change in the resonance frequency is also significantly different.
The adhesive layer 33 is a layer that is detachably adhered to the loop coil sheet 20.
The release sheet 34 is a sheet that protects the adhesive layer 33 before the detection sheet 30 is used.

The detector 40 is coupled to the loop coil 22 by an electromagnetic induction method and communicates with the IC chip 23. The detector 40 has an anti-collision function and can communicate with a plurality of IC chips 23 simultaneously.
The detector 40 is a measurement device arranged in the vicinity of the adherend 2 and the detection device 10.
The detector 40 includes a loop coil 42 and a control unit 43.

The loop coil 42 is a loop coil antenna that performs communication by an electromagnetic induction method. The loop coil 42 is connected to the control unit 43. The loop coil 42 is built in the detector 40.
The loop coil 42 is supplied with a current to generate a magnetic field, and is disposed close to the loop coil 22 (for example, between several tens of mm to 1 m between the loop coils) and is magnetically coupled to the loop coil 22.
The control unit 43 is a control unit 43 that comprehensively controls the detector 40, and includes, for example, a CPU. The control unit 43 appropriately reads and executes various programs stored in a storage device (not shown).
The control unit 43 drives the loop coil 42 and couples it with the loop coil 22 of the detection device 10 by electromagnetic induction, and whether there is a change in the impedance of the loop coil 22, that is, whether there is a change in the characteristic of the resonance frequency of the loop coil 22. Determine. When the detector 40 determines that the characteristic change of the resonance frequency of the loop coil 22 has occurred, the detector 40 drives a notifying unit such as a buzzer (sound output unit) or a lamp (light emitting unit) to notify the measurer. .
Moreover, the control part 43 analyzes the characteristic change of a resonant frequency, determines the kind of gas generated from the to-be-adhered body 2, and displays it on display part apparatuses (not shown), such as a monitor.

(how to use)
The usage method and processing of the detection system 1 will be described.
Here, a case where the detection system 1 is used in a hospital will be described.
The adherend 2 is a diaper 2a and a subject 2b (inpatient etc.), and the measurer is a hospital nurse or the like.
The detection sheet 30 is integrally attached to the diaper in advance with an adhesive or the like, and is delivered to the hospital in a state where it cannot be peeled off.
The detector 40 is installed in advance so that the bed where the subject 2b lies and the surrounding area are within the detection range.

(1) The measurer (or the subject 2b) peels the release sheet 34 of the detection sheet 30 to expose the adhesive layer 33, and adheres and loops the loop coil sheet 20 to the adhesive layer 33. Thereby, the loop coil sheet 20 is attached to the diaper, and the loop coil sheet 20 and the detection sheet 30 are stacked to form the detection device 10. In addition, the diaper with which the loop coil sheet | seat 20 was mounted | worn is called diaper with a loop coil.
A plurality of sets of these diapers with loop coils are prepared in advance.
(2) The subject 2b wears (wears) a diaper with a loop coil.
The steps (1) and (2) may be interchanged, but the loop coil sheet 20 is attached to the detection sheet 30 (above (2)) before the diaper of the subject 2b (above (2)). The method (1)) is preferable because of good workability.

(3) The subject 2b lies on the bed at bedtime or the like. Thereby, the detection apparatus 10 is arrange | positioned in the detection area | region of the detector 40. FIG.
(4) The measurer operates the detector 40 to communicate between the detector 40 and the detection device 10. The detector 40 reads the identification number from the IC chip 23 and displays it on the monitor.

In this case, when the detector 40 communicates with a plurality of IC chips 23, the detector 40 displays a plurality of identification numbers on the monitor. That is, the detector 40 can detect the loop coil sheet 20.
If an identification number larger than the number of subjects 2b is displayed on the monitor, the loop coil sheet 20 alone or a diaper with a loop coil may be misplaced or hidden under a futon or bed, etc. . If the measurer collates these numbers and does not agree, the diaper with a loop coil after use can be cleaned and kept clean.

Furthermore, the measurer can verify whether or not the combination of the detection device 10 and the adherend 2 is correct based on the identification number. For example, when the measurer wants to manage the size (size) of the diaper, an identification number is assigned for each size (for example, the identification numbers 1 to 100 are small and the identification numbers 101 to 200 are large). In the step (1), the loop coil sheet 20 may be attached according to the size of the diaper.
Thereby, the identification number displayed on the monitor is confirmed, and the size of the body of the subject 2b and the size of the diaper worn on the subject (a large diaper is mistakenly applied to the subject 2b having a small body). It can be confirmed whether it is not installed.

(5) The detector 40 is coupled to the loop coil 22 of the detection device 10 by electromagnetic induction, and monitors the change in the resonance frequency characteristics. When the detector 40 determines that the characteristic change of the resonance frequency of the loop coil 22 has occurred, the detector 40 drives the notification unit to notify the measurer.
The detector 40 analyzes the resonance frequency characteristic, determines the type of gas generated from the adherend 2, and displays it on the monitor.

For example, when the subject 2b urinates, water vapor reaches the detection sheet 30 from the diaper through the vent 31a. In this case, the resonance frequency of the loop coil 22 exhibits frequency characteristics corresponding to water vapor. Based on this characteristic, the detector 40 determines that the subject 2b has pissed, displays it on the monitor, and informs the measurer.
On the other hand, when the subject 2b has a stool, the component of hydrogen sulfide mainly reaches the detection sheet 30 from the diaper through the vent 31a. In this case, the resonance frequency of the loop coil 22 exhibits frequency characteristics corresponding to hydrogen sulfide. Based on this characteristic, the detector 40 determines that the subject 2b has stool, displays it on the monitor, and informs the measurer.
As described above, the detector 40 can detect the gas generated from the adherend 2 and detect the dirt of the adherend 2.

(6) The measurer prompts the subject 2b to change to another diaper with a loop coil created in the above (1), and the subject 2b wears another diaper with a loop coil.
(7) The measurer peels the loop coil sheet 20 from the diaper with the loop coil after use. Only the detection sheet 30 remains in the dirty diaper. The measurer discards the diaper. This is because diapers cannot be reused.
(8) The measurer keeps the loop coil sheet 20 peeled off in (7). And the process of said (1) is repeated and it mounts | wears with a new diaper, and produces a new diaper with a loop coil. That is, the loop coil sheet 20 is reused.

  In addition, in the above (1), the example in which the loop coil sheet 20 is attached to the diaper in advance and a plurality of sets of diapers with a loop coil are produced is shown, but the present invention is not limited to this. The loop coil sheet 20 may be attached to a diaper when the diaper is used, and may be attached to another diaper that is removed from the diaper and replaced when the diaper is replaced. In this case, one loop coil sheet 20 may be prepared for each subject.

  As described above, in the detection system 1 of the present embodiment, since the detector 40 detects a change in the impedance of the loop coil 22, it is possible to detect dirt or the like on the adherend 2. Moreover, since the detection system 1 can reuse the loop coil sheet 20, the operation cost can be reduced.

  In the present embodiment, the loop coil 22 may not include the IC chip 23. In this case, detection of the loop coil sheet 20 and the like, and management of the combination of the detection device 10 and the adherend 2 cannot be performed. However, as described above, the detector 40 is attached by detecting the characteristic change of the resonance frequency of the loop coil 22 by the loop coil 42 being coupled to the loop coil 22 of the loop coil sheet 20 by electromagnetic induction. The contamination of the body 2 can be detected.

(Second Embodiment)
Next, a second embodiment of the present invention will be described.
Note that, in the following description and drawings, the same reference numerals or parts (the last one digit) are given the same reference numerals to the portions that perform the same functions as those of the first embodiment described above, and repeated descriptions are omitted as appropriate. To do.

FIG. 4 is a sectional view of the detection device 210 (the loop coil sheet 20 and the detection sheet 230) of the second embodiment (a diagram corresponding to FIG. 2).
The adhesive detection layer 232 of the detection sheet 230 is formed by mixing an adhesive material into the material forming the detection layer. That is, the adhesive detection layer 232 also serves as the detection layer 32 and the adhesive layer 33 of the first embodiment.
As shown in FIG. 4B, for this reason, the loop coil 22 can be placed on the adhesive detection layer 232 itself that is a detection layer. Therefore, the influence of the impedance change which the adhesive detection layer 232 gives to the loop coil 22 can be increased, and the characteristic change of the resonance frequency becomes remarkable. This is because the direction in which the distance between the detection layer and the loop coil 22 is short increases the influence of the adhesive detection layer 232 on the loop coil 22. Thereby, the detection system of this embodiment can improve the precision of the stain | pollution | contamination detection of the to-be-adhered body 2 by a detector (refer FIG. 1).

(Third embodiment)
Next, a third embodiment of the present invention will be described.
FIG. 5 is a cross-sectional view of the detection device 310 (the loop coil sheet 20 and the detection sheet 330) of the third embodiment (a diagram corresponding to FIG. 2).
FIG. 6 is a plan view of the detection device 310 (the loop coil sheet 20 and the detection sheet 330) according to the third embodiment (a view of the surface of the detection sheet 330 viewed from the normal direction).
As shown in FIG. 5, the detection layer 332 and the adhesive layer 333 of the detection sheet 330 are stacked on the same layer.
As shown in FIG. 6, the detection layer 332 is disposed in a region covering the loop coil 22 of the loop coil sheet 20. On the other hand, the adhesive layer 333 is disposed in a region other than the detection layer 332. That is, the area other than the loop coil 22 of the loop coil sheet 20 is adhered to the detection sheet 330 by the adhesive layer 333 and the installation area of the loop coil 22 is in contact with the detection layer 332.
Thereby, the detection system of this embodiment can arrange | position the loop coil 22 on the detection layer 332 itself like 2nd Embodiment, and can improve the precision of the stain | pollution | contamination detection of the to-be-adhered body 2. FIG.

(Fourth embodiment)
Next, a fourth embodiment of the present invention will be described.
FIG. 7 is a cross-sectional view of the detection device 410 (loop coil sheet 420, detection sheet 430) of the fourth embodiment (a diagram corresponding to FIG. 2).
FIG. 8 is a diagram illustrating the positional relationship between the loop coil 22 of the loop coil sheet 420 of the fourth embodiment and the loop coil 435 of the detection layer 432.
As shown in FIGS. 7 and 8, the loop coil 22 of the loop coil sheet 420 is an open circuit. Bumps 426a and 426b (first connection portions) are provided at both ends of the open circuit of the loop coil 22.
The bumps 426 a and 426 b are exposed on the upper surface of the loop coil sheet 420.

The detection layer 432 of the detection sheet 430 includes a loop coil 435 (detection layer loop coil) and bumps 436a and 436b.
The loop coil 435 is formed on the lower surface of the base material 31 by etching or the like. Note that the number of turns of the loop coil 435 of the detection layer 432 is not limited, but it is desirable that the number of turns is single in consideration of cost. This is because the detection layer 432 is discarded after use, as in the first embodiment, and thus low cost is required.
The loop coil 435 is an open circuit. Bumps 436a and 436b (second connection portions) are provided at both ends of the open circuit of the loop coil 435.
The bumps 436a and 436b are exposed on the lower surface of the detection sheet 430 in a state where the release sheet 34 is peeled off. In a state where the detection sheet 430 and the loop coil sheet 420 are overlapped, the bumps 426a and 436a are arranged at positions where they overlap, and the bumps 426b and 436b are arranged at positions where they overlap.
The end of the loop coil 435 bypasses the pattern, and the bumps 426a and 426b are arranged on the left and right sides. That is, the bump 426b at the pattern end from the left side X1 is disposed on the right side X2, while the bump 426a at the pattern end from the right side X2 is disposed on the left side X1.

  With the above configuration, when the release sheet 34 of the detection sheet 430 is peeled and the loop coil sheet 420 is bonded to the detection sheet 430, the bumps 426a and 436a are electrically connected, and the bumps 426b and 436b are electrically connected. Connected to. Thereby, the loop coils 22 and 435 integrally form one loop coil.

In the integrated loop coil, since the pattern end portion of the loop coil 435 is bypassed, the circulation directions of the loop coils 22 and 435 are the same.
As shown in FIG. 8, for example, when a clockwise current flows through the loop coil 22, for example, a clockwise current also flows through the loop coil 435 (see arrow A). Thereby, the magnetic field formed by the loop coils 22 and 435 can improve the detection accuracy of the detector (see FIG. 1) without canceling each other.
Further, the loop coil 435 of the detection sheet 430 is disposed in contact with the detection layer 432. For this reason, the loop coil 435 is easily affected by the detection layer 432, and the detection accuracy can be further improved.

The configuration of this embodiment can also be applied to the second and third embodiments.
FIG. 9 is a cross-sectional view of the detection device 410A (loop coil sheet 420, detection sheet 430A) of the fourth embodiment (a diagram corresponding to FIG. 2).
FIG. 10 is a cross-sectional view of a detection device 410B (loop coil sheet 420, detection sheet 430B) of the fourth embodiment (a diagram corresponding to FIG. 2).
As shown in FIG. 9, the detection device 410A is a form in which the loop coil 435, bumps 436a, 436b, and the like of the fourth embodiment are applied to the second embodiment.
As shown in FIG. 10, the detection device 410B is a form in which the loop coil 435, bumps 436a, 436b, and the like of the fourth embodiment are applied to the third embodiment.
In these forms, since the configuration in which the loop coil 435 and the detection layer 432 of the present embodiment are in contact with the second and third embodiments can be applied, the detection accuracy can be further improved.

(Fifth embodiment)
Next, a fifth embodiment of the present invention will be described.
FIG. 11 is a diagram illustrating the positional relationship between the loop coil 22 of the loop coil sheet 20 and the loop coil 535 of the detection sheet 530 according to the fifth embodiment.
The configuration of the detection system of this embodiment is changed from that of the fourth embodiment.
The loop coil 22 of the loop coil sheet 20 and the loop coil 535 of the detection layer 532 of the detection sheet 530 do not include connection portions such as bumps.
The loop coil sheet 20 has the same configuration as that of the first embodiment, and the loop coil 22 is a closed circuit.
Similarly, the loop coil 535 of the detection layer 532 is a closed circuit.
That is, the loop coil 22 of the loop coil sheet 20 and the loop coil 535 of the detection layer 532 are independent closed loop coils.

  Even in this case, when a current flows through the loop coil 22 of the loop coil sheet 20, a current also flows through the loop coil 535 of the detection layer 532 due to electromagnetic induction. That is, the loop coils 22 and 535 are coupled by an electromagnetic induction method.

Thereby, if the detection layer 532 reacts with the gas generated from the adherend, the resonance coil characteristic change occurs in the loop coil coupled by the electromagnetic induction method. Therefore, the detector (see FIG. 1) can detect the contamination of the adherend 2 by detecting the change in the characteristic of the resonance frequency.
Moreover, since the loop coil 535 is provided in the detection layer 532 itself, the detection accuracy can be improved as in the fourth embodiment.
Furthermore, since the detection system of the present embodiment is not provided with a connection portion such as a bump, it is not affected by contact failure of the connection portion or contact resistance. Thereby, the detection system of this embodiment can detect the stain | pollution | contamination of a to-be-adhered body stably.

  In addition, although detailed description is abbreviate | omitted, you may apply the structure of 2nd, 3rd embodiment mentioned above to the detection system of this embodiment. Even in this case, the same effects as those of the second and third embodiments can be obtained.

(Sixth embodiment)
FIG. 12 is a diagram illustrating the configuration of the detection system 601 of the sixth embodiment (a diagram corresponding to FIG. 1).
FIG. 13 is a cross-sectional view of the detection device 610 (loop coil sheet 620, detection sheet 630) of the sixth embodiment (a figure corresponding to FIG. 2).
As shown in FIG. 12, the detection device 610 includes a loop coil sheet 620 and a detection sheet 630.
As shown in FIGS. 12 and 13, in the detection system 601, the detection device 610 and the detector 640 are electrically connected to each other by cable through cables 660 a and 660 b and connectors 661 a and 661 b. Unlike the above-described embodiment, the detection system 601 directly detects a change in the characteristic of the resonance frequency of the loop coil sheet 620 without using electromagnetic induction coupling, and detects dirt on the adherend 2.

As shown in FIG. 13, the configuration of the detection sheet 630 is the same as that of the first embodiment.
The loop coil sheet 620 includes a loop coil 622, a cable 660a, and a connector 661a.
The loop coil 622 is electrically connected to the lower surface of the base material 21 through the through hole 622a.
The cable 660a is two electric cables. One end of the cable 660a is connected to the lower surface of the base material 21, and is electrically connected to the loop coil 622, respectively. A connector 661a is provided at the other end of the cable 660a.
The connector 661a is detachably connected to the connector 661b on the detector 640 side.

As shown in FIG. 12, the detector 640 is a small box-shaped device having a size of, for example, about 30 mm × 30 mm × 10 mm.
The detector 640 includes a cable 660b, a connector 661b, and a control unit 643.
The cable 660b is two electric cables. Each of the cables 660b is connected to the control unit 643 at one end, and a connector 661b is provided at the other end.
The control unit 643 is a control unit 643 that comprehensively controls the detector 640, and includes, for example, a CPU. The control unit 643 appropriately reads and executes various programs stored in a storage device (not shown).
The control unit 643 is driven by power supplied from a power source such as a built-in battery of the detector 640, for example.
The control unit 643 determines whether or not there is a change in the impedance of the loop coil 622, that is, a characteristic change in the resonance frequency of the loop coil 622. The method of detecting dirt for each type of gas is the same as in the first embodiment.

Although detailed description is omitted, the determination result of the detector 640 is transmitted to a management apparatus (such as a personal computer) that collectively manages the determination result by wireless or wired. The measurer can confirm the measurement result by confirming the monitor of the management device.
In addition, a detector such as a buzzer (sound output unit) and a lamp (light emitting unit) may be provided in the detector 640 itself, and these may be driven to notify the measurer.

(how to use)
The usage method and processing of the detection system 601 will be described.
Here, as in the first embodiment, a case where the detection system 601 is used in a hospital will be described.

(1) Similarly to (1) and (2) of the first embodiment, a diaper with a loop coil is produced, and the subject 2b wears the diaper with a loop coil.
(2) The subject 2b or the measurer connects the connectors 661a and 661b.
(3) The subject 2b lies on the bed at bedtime or the like. In this case, the detector 640 is placed on the stomach of the subject or on the side of the bed. Since the detector 640 is small, even if it is arranged in the vicinity of the subject 2b, it does not interfere with the subject 2b.

(4) The detector 640 monitors the characteristic change of the resonance frequency of the loop coil 622. When the detector 640 determines that the characteristic change of the resonance frequency of the loop coil 622 has occurred, the detector 640 transmits information to the management device and notifies the measurer by driving the notification unit.
In this case, similarly to the first embodiment, the detector 640 can detect the gas generated from the adherend 2 to detect and notify the type of dirt on the adherend 2.

(5) The measurer urges the subject 2b to remove the connectors 661a and 661b and replace them with another diaper with a loop coil created in the above (1). And connector 661b of detector 640 is connected to connector 661a of another diaper with a loop coil. The subject 2b wears another diaper with a loop coil.
(6) The measurer peels off the loop coil sheet 620 from the diaper with a loop coil after use, discards the diaper, and peels the peeled loop coil sheet 620 as in the first embodiment (7) and (8). Keep. And it attaches to a new diaper, produces a new diaper with a loop coil, and reuses the loop coil sheet | seat 620. FIG.

  As described above, the detection system 601 of the present embodiment electrically connects the detection device 610 and the detector 640 by wire, so that the characteristic change of the resonance frequency of the loop coil 622 can be more stable than wireless. Can be detected stably.

The configurations of the second and third embodiments described above can also be applied to the configuration of this embodiment.
FIG. 14 is a cross-sectional view of a detection device 610A (loop coil sheet 620, detection sheet 630A) according to the sixth embodiment (a diagram corresponding to FIG. 2).
FIG. 15 is a cross-sectional view of a detection device 610B (loop coil sheet 620, detection sheet 630B) of the sixth embodiment (a diagram corresponding to FIG. 2).
As shown in FIG. 14, the detection device 610 </ b> A is a form in which an adhesive adhesive 632 </ b> A similar to that of the second embodiment is applied to the sixth embodiment.
As shown in FIG. 15, the detection device 610 </ b> B has a configuration in which a detection layer 632 </ b> B and an adhesive layer 633 </ b> B of the same hierarchy as in the third embodiment are applied to the sixth embodiment.
In these forms, similar to the second and third embodiments, the loop coil 622 of the loop coil sheet 620 can be brought into contact with the adhesive adhesive 632 or the detection layer 632B, so that the detection accuracy can be further improved.

(Seventh embodiment)
FIG. 16 is a diagram illustrating the configuration of a detection system 701 according to the seventh embodiment (a diagram corresponding to FIG. 1).
FIG. 17 is a cross-sectional view and bottom view (viewed from the lower side Z1) of the detection device 710 of the seventh embodiment.
As shown in FIG. 16, in the detection system 701, as in the sixth embodiment, the detection device 710 and the detector 740 are electrically connected by cables with cables 760a and 760b and connectors 761a and 761b. . Unlike the above-described embodiment, the detection system 701 does not detect a change in the characteristic of the resonance frequency, but uses a change in impedance between the copper wires 771 and 772 that are conductive wires to stain the adherend 2. Is detected.

As shown in FIG. 17, the detection device 710 includes a base material 731, a detection layer 732, a cover film 724, copper wires 771, 772, a cable 760a, and a connector 761a.
The cover film 724 is a film that protects the detection layer 732 from being exposed.
The copper wires 771 and 772 are wired in parallel in the detection layer 732 at a predetermined interval. When the detection layer 732 reacts to the gas, the impedance between the copper wires 771 and 772 changes. The detector 740 detects a change in impedance between the copper wires 771 and 772 to detect contamination of the adherend 2.
The cable 760a is two electric cables. One end of the cable 760a is connected to the two copper wires 771, 772, respectively, and one end of the copper wires 771, 772 is connected to the two wires. A connector 761a is provided at the other end of the cable 760a.

As shown in FIG. 16, the detector 740 includes a cable 760b, a connector 761b, and a control unit 743.
The control unit 743 is a control unit 743 that comprehensively controls the detector 740, and includes, for example, a CPU. The control unit 743 appropriately reads and executes various programs stored in a storage device (not shown).
The control unit 743 drives a drive circuit (not shown), applies a constant voltage to the cable 760b, and determines whether there is a change in impedance between the copper wires 771 and 772.

(how to use)
The usage method and processing of the detection system 701 will be described.
Here, as in the first embodiment, a case where the detection system 701 is used in a hospital will be described.
The detection device 710 is processed into a diaper with a detection device that is integrally attached to the diaper in advance with an adhesive or the like, and delivered to the hospital in a state where it cannot be peeled off.

(1) The subject 2b wears a diaper with a detection device.
(2) The subject 2b or the measurement person connects the connectors 761a and 761b.
(3) The detector 740 applies a constant voltage to the cable 760b and monitors whether there is a change in impedance between the copper wires 771 and 772. When the detector 740 determines that an impedance change has occurred between the copper wires 771 and 772, the detector 740 transmits information to the management device and notifies the measurer by driving the notification unit.

(4) The measurer urges the subject 2b to separate the connectors 761a and 761b and replace them with another diaper with a detection device created in (1) above. And connector 761b of detector 740 is connected to connector 761a of another diaper with a detecting device. The subject 2b wears another diaper with a detection device.
(5) The measurer discards the diaper with the detection device after use.

  As described above, the detection system 701 according to the present embodiment can operate the system at low cost because it is only necessary to provide two parallel copper wires 771 and 772 without providing a loop coil by etching or the like. Of course, any material can be selected for the copper wires 771 and 772 as long as they are conductive substances.

  Although the embodiments of the present invention have been described above, the present invention is not limited to the above-described embodiments, and various modifications and changes can be made as in the modifications described later, and these are also included in the present invention. Within the technical scope. In addition, the effects described in the embodiments are merely a list of the most preferable effects resulting from the present invention, and the effects of the present invention are not limited to those described in the embodiments. It should be noted that the above-described embodiment and modifications described later can be used in appropriate combination, but detailed description thereof is omitted.

(Deformation)
In the present embodiment, the detection system has shown an example in which the contamination of the subject is detected. However, the present invention is not limited to this. The detection system only needs to be able to detect the gas generated according to the change in the state of the subject. For example, the gas generated according to the food rot may be detected to detect the food rot. In this case, the detection device may be attached to a container that contains food.

DESCRIPTION OF SYMBOLS 1,601,701 ... Detection system 2 ... Adhering body 10,210,310,410,410A, 410B, 510,610,610A, 610B, 710 ... Detection device 20,420,620 ... Loop coil sheet 22,435, 535, 622 ... Loop coil 23 ... IC chip 30, 230, 330, 430, 430A, 430B, 530, 630, 630A, 630B ... Detection sheet 32, 332, 432, 432B, 532, 632, 632B, 732 ... Detection layer 33, 333, 433, 433B, 633, 633B ... Adhesive layer 40, 640 ... Detector 232, 432A, 632A ... Adhesive sensing layer 426a, 426b, 436a, 436b ... Bump 660a, 660b, 760a, 760b ... Cable 661a, 661b, 761a, 761b ... Connectors 771, 772 ... Copper wire

Claims (17)

A detection system comprising a detection device having a loop coil and a detector for detecting a change in impedance of the loop coil,
The detection device is:
A loop coil sheet having the loop coil;
A detection sheet having an adhesive layer attached to the adherend and detachably bonded to the loop coil sheet; and a detection layer that changes impedance of the loop coil in response to a gas generated from the adherend. Prepared,
The detector is
Coupling with the loop coil by electromagnetic induction to detect a change in impedance of the loop coil;
A detection system featuring. The detection system according to claim 1,
The detection layer has adhesiveness, and also serves as the adhesive layer;
A detection system featuring. The detection system according to claim 1 or 2,
When the surface of the detection sheet is viewed from the normal direction,
The detection layer is disposed in a region covering the loop coil of the loop coil sheet,
The adhesive layer is disposed in a region other than the detection layer;
A detection system featuring. The detection system according to any one of claims 1 to 3,
The loop coil of the loop coil sheet is
An open circuit comprising a first connection at its end;
The sensing layer is
A sensing layer loop coil which is an open circuit;
A second connection portion provided at an end of the detection layer loop coil and electrically connected to the first connection portion;
The loop coil of the loop coil and the detection layer loop coil are connected by the first connection part and the second connection part to form a single loop coil;
A detection system featuring. The detection system according to any one of claims 1 to 3,
The detection layer includes a detection layer loop coil coupled to the loop coil by an electromagnetic induction method;
A detection system featuring. The detection system according to any one of claims 1 to 5,
The loop coil sheet includes an IC chip connected to the loop coil,
The detector is coupled to the loop coil by electromagnetic induction to communicate with the IC chip;
A detection system featuring. A detection sheet on which a loop coil sheet having a loop coil is detachably mounted,
Attached to the adherend,
An adhesive layer that peelably adheres to the loop coil sheet;
A detection layer that changes the impedance of the loop coil in response to a gas generated from the adherend,
In a state where the loop coil sheet is mounted on the detection sheet, a detector can detect a change in impedance of the loop coil by coupling with the loop coil by electromagnetic induction.
Detection sheet characterized by. The detection sheet according to claim 7,
The detection layer has adhesiveness, and also serves as the adhesive layer;
Detection sheet characterized by. In the detection sheet according to claim 7 or claim 8,
When the surface of this detection sheet is viewed from the normal direction,
The detection layer is disposed in a region covering the loop coil of the loop coil sheet,
The adhesive layer is disposed in a region other than the detection layer;
Detection sheet characterized by. In the detection sheet according to any one of claims 7 to 9,
The loop coil of the loop coil sheet is
An open circuit comprising a first connection at its end;
The sensing layer is
A sensing layer loop coil which is an open circuit;
A second connection portion provided at an end of the detection layer loop coil and electrically connected to the first connection portion;
The loop coil of the loop coil and the detection layer loop coil are connected by the first connection part and the second connection part to form a single loop coil;
Detection sheet characterized by. In the detection sheet according to any one of claims 7 to 9,
The detection layer includes a detection layer loop coil coupled to the loop coil by an electromagnetic induction method;
Detection sheet characterized by. A detection system comprising a detection device having a loop coil and a detector for detecting a change in impedance of the loop coil,
The detection device is:
A loop coil sheet having the loop coil;
A detection sheet having an adhesive layer that is attached to the adherend and is detachably bonded to the loop coil sheet; and a detection layer that changes the impedance of the loop coil in response to a gas generated from the adherend. ,
The detector is
Electrically connected to the loop coil by wire, and detecting a change in impedance of the loop coil;
A detection system featuring. The detection system according to claim 12,
The detection layer has adhesiveness, and also serves as the adhesive layer;
A detection system featuring. The detection system according to claim 12 or claim 13,
When the surface of the detection sheet is viewed from the normal direction,
The detection layer is disposed in a region covering the loop coil of the loop coil sheet,
The adhesive layer is disposed in a region other than the detection layer;
A detection system featuring. A detection sheet on which a loop coil sheet having a loop coil is detachably mounted,
Attached to the adherend,
An adhesive layer that peelably adheres to the loop coil sheet;
A detection layer that changes the impedance of the loop coil in response to gas generated from the adherend,
In a state where the loop coil sheet is mounted on the detection sheet, a detector is electrically connected to the loop coil by wire, and a change in impedance of the loop coil can be detected.
Detection sheet characterized by. The detection sheet according to claim 15,
The detection layer has adhesiveness, and also serves as the adhesive layer;
Detection sheet characterized by. The detection sheet according to claim 15 or 16,
When the surface of this detection sheet is viewed from the normal direction,
The detection layer is disposed in a region covering the loop coil of the loop coil sheet,
The adhesive layer is disposed in a region other than the detection layer;
Detection sheet characterized by.

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