JP2016057113A - Tactile sensor and integration sensor - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a tactile sensor that has high sensitivity to a force parallel to a pressure-sensitive surface.SOLUTION: A tactile sensor according to the present invention comprises: a substrate in which a hollow part having an opening is provided; a flexible part provided on the substrate in such a manner that the flexible part covers at least a part of the opening; a projection provided on the flexible part in such a manner that the projection overlaps with the opening; and three or more distortion sensors. The flexible part is deflected toward the hollow part by direct or indirect contact between an object and the projection. The three or more distortion sensors are located around the projection, and provided on or in the flexible part in such a manner that at least a part of each distortion sensor overlaps with the opening. The three or more distortion sensors detect distortion caused by deflection of the flexible part.SELECTED DRAWING: Figure 2

Description

  The present invention relates to a tactile sensor and an integrated sensor.

  When the robot hand grips an object, the robot hand is required to adjust the gripping force appropriately. If the gripping force of the robot hand is too strong, the object may be damaged. In addition, when the gripping force of the robot hand is too weak, an object may slip off from the robot hand. Further, when a fragile object is gripped by the robot hand, the robot hand is required to adjust the gripping force exquisitely. For this reason, a tactile sensor for adjusting the gripping force of the robot hand has been developed.

A tactile sensor including an elastically deformable cantilever and a tactile sensor including a flexible beam are known. (For example, refer to Patent Documents 1 and 2.) In these tactile sensors, the cantilever and the beam are deformed by the force applied to the exterior material, and the force in the direction perpendicular to the pressure-sensitive surface of the sensor or the direction parallel to the pressure-sensitive surface is measured. Detecting force. In these sensors, a laminate is formed on a substrate by a CVD method or the like.
There is also known a tactile sensor in which an opening of a Si substrate is covered with a support film and two piezoelectric bodies are installed on the support film. (For example, refer to Patent Document 3.) With this detection element, the supporting film is deformed by the force applied to the elastic film on the piezoelectric body, and the applied shearing force is detected by measuring the potential difference of the piezoelectric body. Yes.

JP 2014-134543 A JP 2013-68503 A JP 2011-112659 A

However, the conventional tactile sensor has a problem that the sensitivity to a force parallel to the pressure-sensitive surface is not sufficiently high. Further, since the conventional tactile sensor uses a semiconductor substrate, it is difficult to provide it on a curved surface.
The present invention has been made in view of such circumstances, and provides a tactile sensor having high sensitivity to a force parallel to a pressure-sensitive surface.

  The present invention provides a base material provided with a hollow part having an opening, a flexible part provided on the base material so as to cover at least a part of the opening, and the flexible part so as to overlap the opening. A projection provided on the substrate, and three or more strain sensors, wherein the flexible portion is bent toward the hollow portion when an object directly or indirectly contacts the projection. The three or more strain sensors are provided around the protrusion, and are provided on the flexible portion or in the flexible portion so that at least a part of each strain sensor overlaps the opening. Provided is a tactile sensor characterized in that three or more strain sensors detect strain caused by bending of the flexible portion.

According to the present invention, the base material provided with the hollow part having the opening, the flexible part provided on the base material so as to cover at least a part of the opening, and the flexible part so as to overlap the opening. Since the protrusion is provided on the upper portion, the flexible portion can be bent toward the hollow portion by bringing the object into direct or indirect contact with the protrusion. Further, when external pressure is applied to the protrusion from above by contact with the object, the protrusion can be sunk, and the flexible part can be bent. In addition, when external pressure is applied to the protrusion from obliquely or laterally due to contact with the object, or when a friction force is generated between the protrusion and the object, the protrusion is moved by the external pressure or friction force. It can be inclined and the flexible part can be bent. Therefore, the flexible portion can be bent into different shapes depending on the magnitude and direction of the force applied to the protrusion. In addition, when external pressure or frictional force from diagonally above or from the side is applied to the protrusions, the protrusions can be inclined, so the magnitude and direction of the external pressure or frictional force can be changed to the shape of the flexible part with high sensitivity. It can be reflected.
According to the present invention, since the strain sensor is provided on or in the flexible part so that at least a part of the opening overlaps the opening of the hollow part, the object is bent by contacting the protrusion. The distortion of the flexible part can be detected by a strain sensor.
According to the present invention, since three or more strain sensors are arranged around the protrusion, a strain pattern corresponding to the shape of the bent flexible portion can be detected. Since the shape of the flexible portion reflects the magnitude and direction of the force applied to the projection due to contact with the object, pattern analysis of the detected distortion pattern can be used to analyze the magnitude of the force applied to the projection. The direction can be calculated. In addition, by providing three or more strain sensors, the magnitude and direction of the force applied to the protrusion can be detected in three dimensions.

It is a schematic top view of the tactile sensor of one embodiment of the present invention. (A)-(c) is a schematic sectional drawing of the tactile sensor in the dashed-dotted line AA of FIG. It is a schematic top view of the tactile sensor of one embodiment of the present invention. (A)-(d) is a schematic sectional drawing of the tactile sensor of one Embodiment of this invention. (A) (b) is a schematic sectional drawing of the pressure-sensitive resistance part which the distortion sensor contained in the tactile sensor of one Embodiment of this invention has. It is a schematic top view of the integrated sensor of one Embodiment of this invention. It is a schematic top view of the temperature detection sheet | seat contained in the integrated sensor of one Embodiment of this invention. (A)-(c) is a schematic sectional drawing of the measuring apparatus of a pressure-sensitive resistance measurement experiment. It is a graph which shows the measurement result of a pressure sensitive resistance measurement experiment. (A) is a graph which shows the measurement result of distortion detection experiment, (b) is a figure which shows the direction of the load to a projection part. (A) is a graph which shows the measurement result of distortion detection experiment, (b) is a figure which shows the direction of the load to a projection part. (A) is a figure which shows the calculation result of simulation, (b) is a figure which shows the position of the opening of a hollow part. It is a figure which shows the calculation result of simulation. (A) is a graph which shows the measurement result of temperature detection experiment, (b) is a schematic sectional drawing of the measuring apparatus of temperature detection experiment. It is a graph which shows the measurement result of a temperature detection experiment. (A)-(c) is a figure which shows the measurement result etc. of a distortion and temperature detection experiment. (A)-(c) is a figure which shows the measurement result etc. of a distortion and temperature detection experiment. (A)-(c) is a figure which shows the measurement result etc. of a distortion and temperature detection experiment. (A)-(c) is a figure which shows the measurement result etc. of a distortion and temperature detection experiment. (A)-(c) is a figure which shows the measurement result etc. of a distortion and temperature detection experiment. (A)-(c) is a figure which shows the measurement result etc. of a distortion and temperature detection experiment.

  The tactile sensor of the present invention includes a base material provided with a hollow part having an opening, a flexible part provided on the base material so as to cover at least a part of the opening, and the opening so as to overlap the opening. A protrusion provided on the flexible part and three or more strain sensors are provided, and the flexible part faces the hollow part when an object directly or indirectly contacts the protrusion. The three or more strain sensors are arranged around the protrusion, and at least a part of each strain sensor overlaps the opening or in the flexible portion. And three or more strain sensors detect a strain caused by bending of the flexible portion.

In the tactile sensor of the present invention, the substrate preferably has flexibility.
According to such a configuration, the tactile sensor can be arranged on a curved surface or a flexible structure.
In the tactile sensor of the present invention, the strain sensor has a pressure-sensitive resistor portion in which conductive fine particles and carbon nanotubes are kneaded in a polymer material, and detects strain of the flexible portion from the electric resistance value of the pressure-sensitive resistor portion. It is preferable to do.
According to such a configuration, since the pressure-sensitive resistor portion can be formed by a printing method, the pressure-sensitive resistor portion can be easily provided on the flexible sheet or the back surface of the contact member.

In the tactile sensor of the present invention, it is preferable that the hollow portion, the flexible portion, the protrusion, and the three or more strain sensors constitute a sensor element, and a plurality of sensor elements are arranged two-dimensionally.
According to such a configuration, the object can be brought into contact with the protrusions of the plurality of sensor elements, and the size of the object can be detected by the tactile sensor. Moreover, the local slip state and local frictional force between a tactile sensor and a target object can be detected.
The present invention also provides an integrated sensor comprising the tactile sensor of the present invention and a temperature sensor provided on the substrate.
According to the integrated sensor of the present invention, the force applied to the protrusion by the object and the temperature of the object can be detected simultaneously.

  Hereinafter, an embodiment of the present invention will be described with reference to the drawings. The configurations shown in the drawings and the following description are merely examples, and the scope of the present invention is not limited to those shown in the drawings and the following description.

Tactile Sensor and Integrated Sensor FIG. 1 is a schematic top view of a tactile sensor of this embodiment. 2A to 2C are schematic cross-sectional views of the tactile sensor taken along one-dot chain line AA in FIG. 1, and FIGS. 2B and 2C are tactile sensors when the object comes into contact with the protrusion. FIG. FIG. 3 is a schematic top view of the tactile sensor of the present embodiment having a plurality of sensor elements. 4A to 4D are schematic cross-sectional views of the tactile sensor according to the present embodiment, respectively.
The tactile sensor 20 of the present embodiment includes a base material 1 provided with a hollow portion 3 having an opening, a flexible portion 5 provided on the base material 1 so as to cover at least a part of the opening, and the opening. And the projection part 7 provided on the flexible part 5 so as to overlap with the three or more strain sensors 9. The flexible part 5 has the object 13 in direct or indirect contact with the projection part 7. Thus, the three or more strain sensors 9 are arranged around the protrusion 7 and at least a part of each strain sensor 9 can be overlapped with the opening. It is provided on the flexible part 5 or in the flexible part 5 and is characterized in that three or more strain sensors 9 detect distortion caused by the flexible part 5 being bent.
Hereinafter, the tactile sensor 20 and the integrated sensor of this embodiment will be described.

1. Tactile sensor The tactile sensor 20 is a sensor that detects the magnitude and direction of the force applied to the protrusion 7 when the object 13 directly or indirectly contacts the protrusion 7. The tactile sensor 20 may include a sensor element 12 including a hollow portion 3, a flexible portion 5, a protruding portion 7, and three or more strain sensors 9, as shown in FIGS. A plurality of sensor elements 12 may be included as shown in FIG.
The tactile sensor 20 can be used for, for example, a prosthetic hand, a robot, an electronic skin, an input device, an abnormality detection device, a safety device, and the like.

2. Base material, hollow part The base material 1 is a base material of the tactile sensor 20. The substrate 1 may be made of a rigid material or a flexible material, but is preferably made of a flexible material. This makes it possible to arrange the tactile sensor 20 on a curved surface or a flexible structure. Further, when the tactile sensor 20 is provided in the grip portion of the robot hand, if the base material 1 is made of a flexible material, the tactile sensor 20 can be deformed in accordance with the shape of the object 13, and the object 13 can be stabilized. And can be gripped. The material of the substrate 1 is, for example, silicone rubber.

The substrate 1 has a hollow portion 3. Thereby, the flexible part 5 can be bent toward the hollow part 3, and the magnitude and direction of the force applied to the protrusion 7 can be detected using the bending of the flexible part 5. The hollow portion 3 has an opening, and the flexible portion 5 covers at least a part of the opening.
The hollow portion 3 only needs to be a space in which the flexible portion 5 can be bent, and may be a through hole provided in the base material 1 or a bottomed hole. The shape of the opening of the hollow portion 3 may be circular, square, or polygonal, but is preferably circular. By making the shape of the opening of the hollow portion 3 circular, the projection 7 can be provided at the center, and three or more strain sensors 9 can be provided at equal intervals on the circumference. As a result, the magnitude and direction of the force applied to the protrusion 7 by the tactile sensor 20 can be detected with high sensitivity. The diameter or width of the opening of the hollow portion 3 can be set to, for example, 0.01 mm or more and 10 mm or less.
The depth of the hollow part 3 can be made deeper than 1/16 of the diameter (or width) of the opening of the hollow part 3, for example, and shallower than 1/4. As a result, when a large force is applied to the protrusion 7, the flexible portion 5 can be brought into contact with the bottom of the hollow portion 3 or an object under the tactile sensor 20, and the flexible portion 5 and the strain sensor 9 are damaged. Can be suppressed.

  When the tactile sensor 20 has a plurality of sensor elements 12 as shown in FIG. 3, a plurality of hollow portions 3 are provided in the base material 1, and a flexible portion 5, a strain sensor 9, and a protruding portion 7 are provided on each hollow portion 3. By providing, a plurality of sensor elements 12 can be provided. Further, when the tactile sensor 20 includes a plurality of sensor elements 12, each sensor element 12 may include the substrate 1.

3. Flexible part, protrusion part, strain sensor The flexible part 5 is provided on the base material 1 so as to cover the opening of the hollow part 3. Further, the protruding portion 7 is provided on the flexible portion 5 so as to overlap the opening of the hollow portion 3. Accordingly, as shown in FIGS. 2B and 2C, the flexible portion 5 can be bent toward the hollow portion 3 by bringing the object 13 into direct contact or indirect contact with the protruding portion 7. .
The flexible portion 5 may be provided on the base material 1 so as to cover the entire opening of the hollow portion 3, or may be provided on the base material 1 so as to cover a part of the opening of the hollow portion 3. It is preferably provided so as to cover the entire opening of the hollow portion 3. By covering the entire opening of the hollow portion 3 with the flexible portion 5, the entire periphery of the flexible portion 5 can be fixed to the substrate 1, and the shape of the flexible portion 5 when a force is applied to the protruding portion 7. Changes can be stabilized. In addition, a material having high flexibility can be used for the flexible portion 5.

  The flexible part 5 is, for example, as shown in FIGS. 1 and 2, a contact provided with a flexible sheet 6 provided on the base material 1 and a columnar protrusion 7 provided on the flexible sheet 6. A part of the member 8 may be included. In this case, the material of the flexible sheet 6 can be a polymer material such as polyethylene or silicone rubber, and the material of the contact member 8 can be a polymer material such as silicone rubber. Moreover, the flexible part 5 may be comprised from the flexible sheet | seat 6 like FIG.4 (a) (b) (d), and is comprised from a part of contact member 8 like FIG.4 (c). May be.

The protrusion 7 may be all or part of the contact member 8 that is in direct or indirect contact with the object 13. Further, the contact member 8 may be a member that constitutes both the protruding portion 7 and the flexible portion 5 as shown in FIGS. 2 and 4C. In this case, the material of the contact member 8 can be a flexible material such as silicone rubber. Further, the contact member 8 may be a member constituting the protrusion 7 as shown in FIGS. 4 (a), 4 (b), and 4 (d). In this case, the material of the contact member 8 may be a rigid material or a flexible material.
In addition, when the projection part 7 contacts indirectly with the target object 13, the cover etc. are provided on the tactile sensor 20, and the case where the target object 13 contacts the projection part 7 from on a cover etc. is included.

The shape of the protruding portion 7 is not particularly limited as long as it is a shape protruding from the flexible portion 5. For example, the protruding portion 7 may be cylindrical as shown in FIGS. 2 and 4A to 4C. It may be dome-shaped as in (d). Thereby, the direction of the force applied to the protrusion 7 by the tactile sensor 20 can be detected with high sensitivity. The diameter or width of the protrusion 7 can be, for example, not less than ¼ and not more than ¼ of the diameter or width of the opening of the hollow portion 3. Moreover, the height of the projection part 7 can be made into 1/8 or more and 8/8 or less of the diameter or width | variety of the opening of the hollow part 3, for example.
The protruding portion 7 may be provided on the flexible portion 5 so as to overlap the central portion of the hollow portion 3. As a result, the magnitude and direction of the force applied to the protrusion 7 by the tactile sensor 20 can be detected with high sensitivity.

  The strain sensor 9 is provided on or in the flexible part 5 so that at least a part thereof overlaps the opening of the hollow part 3. Further, the strain sensor 9 can be provided on or in the flexible portion 5 so as to overlap both the base material 1 around the opening of the hollow portion 3 and the opening of the hollow portion 3. Thus, the strain sensor 9 can detect the distortion of the flexible portion 5 that is bent when the object 13 directly or indirectly contacts the protrusion 7. As shown in FIG. 2A, the strain sensor 9 may be provided between the flexible sheet 6 constituting the flexible portion 5 and the contact member 8. Further, the strain sensor 9 may be provided on the upper surface of the flexible sheet 6 as shown in FIGS. 4 (a) and 4 (d), and provided on the back surface of the flexible sheet 6 as shown in FIG. 4 (b). May be. Further, the strain sensor 9 may be provided on the back surface of the contact member 8 as shown in FIG.

The strain sensor 9 is not particularly limited as long as it can detect a strain caused by the flexible portion 5 being bent. The strain sensor 9 may have a pressure-sensitive resistance portion 10 in which conductive fine particles are kneaded in a polymer material.
5A and 5B are schematic cross-sectional views of the pressure-sensitive resistor unit 10 included in the strain sensor 9 included in the tactile sensor 20 of the present embodiment. The strain sensor 9 has a pressure-sensitive resistor portion 10 in which conductive fine particles 16 and carbon nanotubes 17 are kneaded in a polymer material 15, and detects the strain of the flexible portion 5 from the electric resistance value of the pressure-sensitive resistor portion 10. It may be a sensor. Since such a pressure-sensitive resistance portion 10 can be formed by a printing method such as screen printing, it can be easily provided on the flexible sheet 6 or the back surface of the contact member 8. The wiring 11 for measuring the electric resistance value of the pressure-sensitive resistor portion 10 can be formed on the same surface as the pressure-sensitive resistor portion 10 by a printing method.

  FIG. 5A is a schematic cross-sectional view of the pressure-sensitive resistor portion 10 that is not deformed, and FIG. 5B is a schematic cross-sectional view of the pressure-sensitive resistor portion 10 that has one end deformed downward and extended. When a current is passed through the pressure-sensitive resistor portion 10, the current mainly flows through the conductive fine particles 16. As shown in FIG. 5B, when the pressure-sensitive resistor portion 10 expands, the contact area of the conductive fine particles 16 becomes narrow, so that the electric resistance of the pressure-sensitive resistor portion 10 increases. On the contrary, when the pressure-sensitive resistor portion 10 is compressed, the contact area of the conductive fine particles 16 is increased, so that the electric resistance of the pressure-sensitive resistor portion 10 is reduced. Therefore, the strain of the flexible part 5 can be measured by providing the pressure-sensitive resistor part 10 so as to be deformed together with the bending of the flexible part 5 and measuring the electric resistance value of the pressure-sensitive resistor part 10.

Around the protrusion 7, three or more strain sensors 9 are arranged. In addition, three or more strain sensors 9 can be arranged at equal intervals along the edge of the opening of the hollow portion 3. By detecting the strain with three or more strain sensors 9, it is possible to detect a strain pattern corresponding to the shape of the flexed flexible portion 5. By analyzing the distortion pattern, the magnitude and direction of the force applied to the protrusion 7 can be detected. Further, by detecting with three or more strain sensors 9, the magnitude and direction of the force applied to the protrusion 7 can be detected in three dimensions.
The number of strain sensors 9 around the protrusion 7 may be 3 or more, 6 or less, 4 or 7 or less, or 5 or more and 8 or less. , 6 or more and 10 or less. By increasing the number of strain sensors 9, the resolution for detecting the direction of the force applied to the protrusion 7 can be increased.

  For example, as shown in FIG. 2B, when the object 13 is brought into contact with the protrusion 7 from above, the protrusion 7 can be sunk by the pressure from the object 13, and the flexible part 5 is bent. I can do it. In this case, distortion occurs substantially uniformly in the bent flexible portion 5 around the protrusion 7, and the three or more strain sensors 9 provided around the protrusion 7 detect equivalent distortion. Therefore, by detecting the strain with the three or more strain sensors 9, it is possible to detect that the object 13 is in contact with the protrusion 7 and pressure is applied to the protrusion 7 from above.

For example, as shown in FIG. 2C, when the object 13 is brought into contact with the protrusion 7 and pressure is applied to the protrusion 7 obliquely or from the side, frictional force is generated between the protrusion 7 and the object 13. When this occurs, the protrusion 7 can be inclined by the pressure and frictional force, and the flexible portion 5 can be bent.
In this case, in the flexible portion 5 that is bent around the protruding portion 7, uneven distortion occurs due to the direction of pressure or frictional force. Therefore, the three or more strain sensors 9 provided around the protrusion 7 detect different strains depending on the direction of pressure or frictional force. Accordingly, the magnitude and direction of the force applied to the protrusion 7 can be detected from the strain patterns of the three or more strain sensors 9. Further, by increasing the number of strain sensors 9 around the protrusions 7, the resolution of the direction of force detected by the tactile sensor 20 can be increased.
Further, when pressure or frictional force from obliquely above or from the side is applied to the protruding part 7, the protruding part 7 can be inclined, so that the flexible part flexes the pressure or frictional force with high sensitivity or direction. 5 can be reflected. Since the distortion caused by the bending of the flexible portion 5 can be detected by the three or more strain sensors 9, the direction of the force applied to the protruding portion 7 can be detected with high sensitivity.

  In addition, the relationship between the magnitude and direction of the force applied to the protrusions 7 and the distortion patterns of the three or more distortion sensors 9 can be examined and databased in advance. Thus, the magnitude and direction of the force applied to the protrusion 7 can be calculated by comparing the measured strain pattern with the strain pattern in the database and performing pattern analysis.

As shown in FIG. 3, the tactile sensor 20 includes a plurality of sensor elements 12 including a hollow portion 3, a flexible portion 5, a protrusion 7, and three or more strain sensors 9, and the plurality of sensor elements 12 are arranged two-dimensionally. In such a case, detection of external pressure or the like by the plurality of sensor elements 12 can be performed in parallel. In this case, the object 13 can be brought into contact with the protrusions 7 of the plurality of sensor elements 12, and the size of the object 13 can be detected by the tactile sensor 20. In addition, a local slip state and a local frictional force between the tactile sensor 20 and the object 13 can be detected. Accordingly, when the tactile sensor 20 is installed in a robot hand or the like, it becomes possible to grip the target 13 whose weight or friction coefficient is unknown.
The detection of the force applied to the protrusion 7 by the plurality of sensor elements 12 may be detected at the same time or sequentially by switching the switch.

4). Integrated Sensor, Temperature Sensor The integrated sensor 30 includes the tactile sensor 20 of the present embodiment and the temperature sensor 22 provided on the substrate 1. For this reason, the integrated sensor 30 can simultaneously detect the force applied to the protrusion 7 by the object 13 and the temperature of the object 13.
FIG. 6 is a schematic top view of the integrated sensor 30 of the present embodiment, and FIG. 7 is a schematic top view of the temperature detection sheet 28 included in the integrated sensor 30 of the present embodiment. The integrated sensor 30 shown in FIG. 6 has a structure in which the temperature detection sheet 28 shown in FIG. 7 is superimposed on the tactile sensor 20 shown in FIG.

The temperature sensor 22 provided in the integrated sensor 30 is not particularly limited as long as it can measure the temperature of the object 13, but may be a thermocouple, and a resistance temperature sensor whose electric resistance value changes depending on the temperature. The sensor provided with the part may be used. The temperature sensor 22 is preferably a sensor provided with a temperature measuring resistance unit. Thereby, the temperature sensor 22 can be formed by a printing method or the like.
The temperature sensor 22 may be provided directly on the substrate 1, may be provided on the flexible sheet 6, may be provided on the contact member 8, or may be provided on the temperature sensor sheet 24. Good. When the temperature sensor 22 is provided on the temperature sensor sheet 24 as shown in FIG. 7 and the temperature detection sheet 28 is formed, the temperature detection sheet 28 is stacked and adhered to the tactile sensor 20 as shown in FIG. The sensor 30 can be formed. In this case, since the temperature sensor 22 and the temperature sensor wiring can be formed on the temperature sensor sheet 24, the strain sensor wiring 11 and the temperature sensor wiring can be laminated, and the integrated sensor. 30 can be miniaturized. Further, by providing the contact member opening 26 in the temperature sensor sheet 24, it is possible to prevent the temperature sensor sheet 24 from overlapping the protrusion 7.

Pressure Sensitive Resistance Measurement Experiment A strain sensor 9 was produced, and the relationship between the strain of the silicone rubber sheet 32 and the electric resistance value of the pressure sensitive resistor 10 was examined.
First, the pressure-sensitive resistance portion 10 was formed by applying and drying a paste prepared by kneading silver fine particles into carbon nanotube (CNT) ink on a silicone rubber (PDMS) sheet 32 having a thickness of 0.5 mm. As shown in FIG. 8, the PDMS sheet 32 was fixed to the sample stage 33 so that the PDMS sheet 32 and the pressure-sensitive resistor portion 10 overhang. And the position of the edge part of PDMS sheet 32 was displaced like FIG.8 (b) (c), and the electrical resistance value of the pressure sensitive resistance part 10 was measured. When the position of the end portion of the PDMS sheet 32 is displaced as shown in FIG. 8B, the pressure-sensitive resistance portion 10 is extended by a tensile load, and the PDMS sheet 32 as shown in FIG. 8C. When the position of the end portion is displaced, the pressure sensitive resistance portion 10 is compressed by the compressive load.

The results of the pressure sensitive resistance measurement experiment are shown in FIG. 9 shows the electric resistance value R of the pressure-sensitive resistor portion 10 as the electric resistance value R ₀ of the pressure-sensitive resistor portion 10 when no load is applied to the pressure-sensitive resistor portion 10 as shown in FIG. The relationship between the value divided by 1 and the displacement of the end of the PDMS sheet 32 is shown.
9 that the electrical resistance value of the pressure-sensitive resistor unit 10 increases when the pressure-sensitive resistor unit 10 extends, and the electrical resistance value of the pressure-sensitive resistor unit 10 decreases when the pressure-sensitive resistor unit 10 is compressed. . It was also found that R / R ₀ varied from 0.04 to 50. Therefore, it was found that the strain in the PDMS sheet 32 can be detected by providing the pressure-sensitive resistor portion 10 together with the PDMS sheet 32 so as to change its shape and measuring the electric resistance value of the pressure-sensitive resistor portion 10.

Distortion detection experiment As shown in FIGS. 2B and 10B, a tactile sensor 20 in which four strain sensors 9a to 9d as shown in FIGS. The change of the electric resistance value of the pressure-sensitive resistance part 10 of the strain sensors 9a to 9d was measured by applying a load of about 0.3 seconds to the protrusion part 7 with a finger from substantially above and bending the flexible part 5. In addition, the base material 1 was made of a polyester sheet, the flexible sheet 6 was made of a polyethylene (PE) sheet, and the contact member 8 was made of silicone rubber (PDMS). The strain sensor 9 is prepared by screen-printing a paste prepared by kneading silver fine particles in CNT ink on the flexible sheet 6, and the wiring 11 is screen-printed with the silver paste on the flexible sheet 6. It was produced by. The opening of the hollow portion 3 was a circle with a diameter of 5 mm, and the protrusion 7 was a cylinder with a diameter of 2 mm and a height of 1 mm.
The measurement results are shown in FIG. In FIG. 10A, the electric resistance value of the pressure-sensitive resistor unit 10 is converted into the pressure applied to the pressure-sensitive resistor unit 10.
As shown in FIG. 10A, the strain sensors 9a and 9d measured a pressure of about 15 mN, and the strain sensors 9b and 9c measured a pressure of about 12 mN. Accordingly, it was found that when the load is applied to the protrusion 7 from substantially above, the pressures measured by the strain sensors 9a to 9d are substantially the same.

Next, as shown in FIG. 2 (c) and FIG. 11 (b), a load from an obliquely upward direction from the strain sensor 9a toward the strain sensor 9c is applied to the protrusion 7 with a finger for about 0.3 seconds, and the flexible portion 5 is moved. The change in the electric resistance value of the pressure-sensitive resistor portion 10 of the strain sensors 9a to 9d was measured by bending.
The measurement results are shown in FIG. In FIG. 11A, the electric resistance value of the pressure-sensitive resistor unit 10 is converted into a pressure applied to the pressure-sensitive resistor unit 10.
As shown in FIG. 11A, a pressure of about 13 mN is measured in the strain sensor 9c arranged in the load direction, and a pressure of about 8.5 mN is measured in the strain sensor 9a arranged to face the strain sensor 9c. Was measured. Further, a pressure of about 5 mN was measured in the strain sensors 9b and 9c. Accordingly, it was found that when a load from an obliquely upward direction is applied to the protrusion 7, the highest pressure is measured by the strain sensor arranged in the load direction.

Simulation For the tactile sensor 20 as shown in FIGS. 1 and 2, a simulation was performed on the distortion of the flexible portion 5 when a load of −20 mN (a load from above) was applied to the protrusion 7 in the z direction. The opening of the hollow portion 3 was calculated as a circle having a diameter of 5 mm as shown in FIG.
The simulation result is shown in FIG. As shown in FIG. 12, it was found that when a load was applied to the protrusion 7 from above, pressure was applied in a circular shape along the edge of the opening. Therefore, it is considered that the four strain sensors 9a to 9d detect equivalent strain. This result agrees with the measurement result of the strain detection experiment shown in FIG.
Therefore, when the strains measured from the four strain sensors 9a to 9d are substantially equal, it can be detected by the tactile sensor 20 that the object 13 has contacted the protrusion 7 from above.

Next, with respect to the tactile sensor 20 as shown in FIGS. 1 and 2, the flexible portion 5 when a load of 20 mN in the x direction and −10 mN in the z direction (a load from an obliquely upward direction) is applied to the protrusion 7. A simulation was performed for distortion. The opening of the hollow part 3 was calculated as a diameter of 5 mm.
The simulation result is shown in FIG. As shown in FIG. 13, it was found that when a load is applied to the protrusion 7 from an obliquely upward direction, a large pressure is applied in the vicinity of the strain sensor 9c disposed in the load direction. Therefore, it is considered that the largest strain is detected by the strain sensor 9c among the four strain sensors 9a to 9d. This result agrees with the measurement result of the strain detection experiment shown in FIG.
Therefore, when the strain measured from one strain sensor 9c among the strains measured from the four strain sensors 9a to 9d is particularly large, a load from an obliquely upward direction toward the strain sensor 9c is applied to the protrusion 7. Can be detected by the tactile sensor 20.

Temperature sensor 22 A temperature sensor 22 having a temperature measuring resistance unit was manufactured, and the temperature responsiveness of the temperature sensor 22 was examined. The resistance temperature detector was prepared by printing a paste prepared by kneading the polymer material PEDOT: PSS on the CNT ink on the temperature sensor sheet 24. The manufactured temperature sensor 22 is arranged as shown in FIG. 14B, and a heating object 35 at 60 ° C. is arranged at a location 1 mm above the temperature sensor 22 for about 57 seconds to change the electric resistance value of the resistance temperature measuring section. It was measured. The measurement results are shown in FIG. FIG. 14A shows the relationship between the amount of change ΔR in the electrical resistance value of the resistance temperature detector and time.
As shown in FIG. 14A, the electric resistance value changed about 10% in about 20 seconds after the heating object 35 was arranged. Further, ΔR recovered to about 2% in about 50 seconds after removing the heated object 35.

  Next, using a heating object 35 of 22 ° C. to 80 ° C., the change in the electrical resistance value of the resistance temperature detector was measured in the same manner, and the change ΔR in the electrical resistance value of the resistance temperature detector was examined. The measurement results are shown in FIG. Note that ΔR shown in FIG. 15 is ΔR when the heating object 35 is arranged and the electric resistance value is stabilized. As shown in FIG. 15, it was found that the amount of change ΔR in the electrical resistance value of the resistance temperature detector increases in proportion from 22 ° C. to 80 ° C. as the temperature increases. The sensitivity was 0.25% / ° C. Therefore, it was found that the temperature of the heated object 35 1 mm above can be measured by the produced temperature sensor 22.

Strain / temperature detection experiment A tactile sensor 20 having nine sensor elements 12a to 12i as shown in FIG. 3 was produced. Further, a temperature detection sheet 28 as shown in FIG. 7 was produced. Then, an integrated sensor 30 as shown in FIG. 6 was manufactured by superimposing the temperature detection sheet 28 on the tactile sensor 20. The manufacturing method of the tactile sensor 20 is the same as the above-described distortion detection experiment. The interval between adjacent protrusions 7 was 15 mm.
The temperature detection sheet 28 was prepared by printing a paste prepared by kneading a polymer material PEDOT: PSS on a CNT ink on a temperature sensor sheet 24 made of polyethylene terephthalate to form the temperature sensor 22. The temperature sensor 22 was provided so as to be close to the sensor elements 12a to 12i.

First, as shown in FIG. 16A, a load is applied to the protrusion 7 from above the protrusion 7 of the sensor element 12f included in the integrated sensor 30, and measurement is performed by each strain sensor 9 and each temperature sensor 22. It was. The results are shown in FIGS. 16 (b) and 16 (c). As shown in FIG. 16B, the same pressure was detected by the four strain sensors 9 of the sensor element 12f. From this, the integrated sensor 30 could detect that a load was applied to the protrusion 7 from above the protrusion 7 of the sensor element 12f. Further, as shown in FIG. 16C, the highest temperature was measured by the temperature sensor 22 installed close to the sensor element 12f. From this, it was possible to detect by the integrated sensor 30 that the high-temperature object 13 approached the sensor element 12f.
Therefore, the position where the object 13 is in contact with the integrated sensor 30, the magnitude of the pressure, the direction of the pressure, and the temperature due to this contact could be detected simultaneously.

  Next, as shown in FIG. 17A, a load is applied to the protrusion 7 with a finger from above the protrusion 7 of the sensor element 12e included in the integrated sensor 30, and measurement is performed by each strain sensor 9 and each temperature sensor 22. went. The results are shown in FIGS. 17 (b) and 17 (c). As shown in FIG. 17B, the same pressure was detected by the four strain sensors 9 of the sensor element 12e. From this, the integrated sensor 30 could detect that a load was applied to the protrusion 7 from above the protrusion 7 of the sensor element 12e. Further, as shown in FIG. 17C, the highest temperature was measured by the temperature sensor 22 installed close to the sensor element 12e. From this, it was possible to detect by the integrated sensor 30 that the high-temperature object 13 approached the sensor element 12e.

Next, as shown in FIG. 18A, a load is applied to the protrusion 7 with a finger from above the protrusions 7 of the sensor elements 12d and 12g included in the integrated sensor 30, and each strain sensor 9 and each temperature sensor 22 Measurements were made. The results are shown in FIGS. 18 (b) and 18 (c). As shown in FIG. 18B, equivalent pressures were detected by the four strain sensors 9 in the sensor elements 12d and 12g, respectively. From this, the integrated sensor 30 could detect that a load was applied to the protrusion 7 from above the protrusions 7 of the sensor elements 12d and 12g. Moreover, as shown in FIG.18 (c), high temperature was measured with the two temperature sensors 22 installed close to the sensor elements 12d and 12g. From this, it was possible to detect by the integrated sensor 30 that the high-temperature object 13 approached the sensor elements 12d and 12g.
Therefore, the pressure or the like can be detected simultaneously by the plurality of sensor elements 12 included in the integrated sensor 30.

  Next, as shown in FIG. 19A, a load was applied to the protrusion 7 of the sensor element 12d included in the integrated sensor 30 from the diagonally upward direction with a finger, and measurement was performed with each strain sensor 9 and each temperature sensor 22. . The results are shown in FIGS. 19 (b) and 19 (c). As shown in FIG. 19B, a high pressure was detected by one of the four strain sensors 9 from the sensor element 12d. From this, it was possible to detect by the integrated sensor 30 that a load in an oblique direction toward the strain sensor 9 where this high pressure was detected was applied to the protrusion 7 of the sensor element 12d. Moreover, as shown in FIG.19 (c), high temperature was measured with the temperature sensor 22 installed close to the sensor element 12d. From this, it was possible to detect by the integrated sensor 30 that the high-temperature object 13 approached the sensor element 12d.

  Next, as shown in FIG. 20A, a load was applied to the protrusion 7 of the sensor element 12 b included in the integrated sensor 30 from the diagonally upward direction with a finger, and measurement was performed with each strain sensor 9 and each temperature sensor 22. . The results are shown in FIGS. 20 (b) and 20 (c). As shown in FIG. 20B, a high pressure was detected by one of the four strain sensors 9 of the sensor element 12b. From this, it was possible to detect by the integrated sensor 30 that a load in an oblique direction toward the strain sensor 9 where this high pressure was detected was applied to the protrusion 7 of the sensor element 12b. Moreover, as shown in FIG.20 (c), high temperature was measured with the temperature sensor 22 installed close to the sensor element 12b. From this, it was possible to detect by the integrated sensor 30 that the high-temperature object 13 approached the sensor element 12b.

  Next, as shown in FIG. 21A, a load is applied to the protrusions 7 of the sensor elements 12c and 12f included in the integrated sensor 30 from the diagonally upward direction with a finger, and measurement is performed with each strain sensor 9 and each temperature sensor 22. went. The results are shown in FIGS. 21 (b) and 21 (c). As shown in FIG. 21B, a high pressure is detected by one of the four strain sensors 9 of the sensor element 12c, and two strain sensors 9 of the four strain sensors 9 of the sensor element 12f are detected. A high pressure was detected. From this, in the sensor element 12c, it was possible to detect by the integrated sensor 30 that a load in an oblique direction toward the strain sensor 9 where this high pressure was detected was applied to the protrusion 7 of the sensor element 12c. The sensor element 12f could not detect the direction in which the load was applied. This is presumably because the load applied to the protrusion 7 was too large. Further, as shown in FIG. 21C, a high temperature was measured by the temperature sensor 22 installed in the vicinity of the sensor elements 12c and 12f. From this, it was possible to detect by the integrated sensor 30 that the high-temperature object 13 approached the sensor elements 12c and 12f.

  DESCRIPTION OF SYMBOLS 1: Base material 3: Hollow part 5: Flexible part 6: Flexible sheet 7: Protrusion part 8: Contact member 9, 9a, 9b, 9c, 9d: Strain sensor 10: Pressure-sensitive resistance part 11: Wiring 12: Sensor Element 13: Object 14: Connection terminal 15: Polymer material 16: Conductive fine particle 17: Carbon nanotube 20: Tactile sensor 22: Temperature sensor 24: Temperature sensor sheet 26: Contact member opening 28: Temperature detection sheet 30: Integrated sensor 32: Silicone rubber sheet 33: Sample stage 35: Heated object

Claims (5)

A base provided with a hollow part having an opening; a flexible part provided on the base so as to cover at least a part of the opening; and provided on the flexible part so as to overlap the opening. A protrusion and three or more strain sensors,
The flexible portion is provided so that the object is bent toward the hollow portion by directly or indirectly contacting the protrusion,
Three or more strain sensors are arranged around the protrusion, and are provided on or in the flexible portion such that at least a part of each strain sensor overlaps the opening,
3. A tactile sensor, wherein three or more strain sensors detect a strain caused by bending of the flexible portion.   The tactile sensor according to claim 1, wherein the base material has flexibility.   The strain sensor includes a pressure-sensitive resistance portion in which conductive fine particles and carbon nanotubes are kneaded in a polymer material, and detects strain of the flexible portion from an electric resistance value of the pressure-sensitive resistance portion. Or the tactile sensor of 2. The hollow portion, the flexible portion, the protrusion, and the three or more strain sensors constitute a sensor element,
The tactile sensor according to any one of claims 1 to 3, wherein the plurality of sensor elements are arranged two-dimensionally.   An integrated sensor comprising the tactile sensor according to claim 1 and a temperature sensor provided on the substrate.