KR101971661B1 - Multi axis strain sensor measurement system and multi axis strain sensor measurement method - Google Patents

Abstract

The present invention relates to a multiaxial strain sensor measurement system and a method for measuring a multiaxial strain sensor, which comprises a polymer composite material according to an embodiment of the present invention and a sensor portion including a plurality of electrodes disposed at the edges of the polymer composite material, An electric current is applied to a pair of electrodes of the electrode, and a voltage is measured through a pair of the remaining electrodes to sense piezoresistance anisotropic deformation.

Description

TECHNICAL FIELD [0001] The present invention relates to a multi-axis strain sensor measurement system and a multi-axis strain sensor measurement method. [0002] MULTI-AXIS STRAIN SENSOR MEASUREMENT SYSTEM AND MULTI AXIS STRAIN SENSOR MEASUREMENT METHOD [

The present invention relates to a multi-axis strain sensor measurement system and a multi-axis strain sensor measurement method.

Flexible strain sensors that can operate on large deformations are technologies of recent interest, which can provide soft touch in the interaction between human and robot and provide safety against external impact applied to the robot itself. For this reason, attention has been recently drawn from artificial skin to biomimetic technology, rehabilitation engineering and the entertainment industry.

A tactile sensor is a sensor specially designed to measure the pressure distribution across a wide range of human skin by aligning individual sensors. The tactile sensor is a tactile sensor that is flexible and stretchable. It can be used for development.

A very flexible tactile sensor can be applied to a robot having a curved surface shape and can be applied to a human skin. In order to develop such flexible tactile sensors, it is common to use flexible electrodes arranged to cover a wide range of contact areas. However, the process of fabricating flexible electrodes for data acquisition together with a flexible sensing material requires many MEMS processes when using a thin metal film, or when the conductive rubber is used, materials for the dysplastic material must be separately manufactured. . In addition, in fields such as artificial skin or entertainment interface of a robot, it is possible to grasp only the position, strength and direction of contact rather than high-precision measurement like a human skin, and it can be manufactured in various shapes, and can be mass- A technology for developing a sensor is required. Tactile sensors using a method called electrical resistance tomography have been developed in response to these demands. This method is a method of estimating the resistance distribution inside a conductive material by arranging electrodes on the surface of a conductive material, measuring current after applying current, and there is no need to fabricate a flexible electrode. It is a great advantage to develop practical flexible tactile sensor.

However, the previously developed resistance tester (ERT) tactile sensor has calculated an isotropic scalar resistance distribution and mapped the resistance value at each position to the force applied in the vertical direction of the sensor plane. However, the proposed resistance tester (ERT) tactile sensor uses anisotropic two-dimensional tensor-type resistance distributions and uses the resistance values in different directions at each position to calculate the vertical force applied to the sensor plane At the same time, the tension in the transverse direction of the sensor can be estimated.

The following prior art documents relate to a strain sensor system, which includes a tactile sensor using a conductive material. Tactile sensing in the direction perpendicular to the conductive material is possible, but no technique for measuring the transverse tension of the conductive material has been disclosed.

 T. Someya et al., &Quot; A large-area, flexible pressure sensor matrix with organic field-effect transistors for artificial skin applications. &Quot; , Proc. Natl. Acad. Sci. U. S. A., vol. 101, no. 27, pp. 9966-9970, 2004.  T. F. Tsuyoshi Sekitani et al., &Quot; A Rubbery Stretchable Active Matrix Using Elastic Conductors, " Science (80-.). September, pp. 1468-1472, 2008.

An object of the present invention is to provide a multi-axis strain sensor system capable of measuring multi-axis strain using a highly flexible conductive polymer composite material.

It is another object of the present invention to provide a method for measuring a multi-axial strain which converts an external stimulus to a multi-axial strain more accurately.

A multi-axis strain sensor system according to an embodiment of the present invention includes a polymer composite material and a sensor unit including a plurality of electrodes disposed at edges of the polymer composite material, wherein a current is applied to a pair of electrodes of the plurality of electrodes, The voltage in the polymer composite is measured through a pair of electrodes to sense the piezoresistance anisotropic resistance to deformation of the polymer composite.

In addition, the electrode to which the current is applied and the electrode for measuring the potential value may be sequentially changed.

Further, the resistance change of the polymer composite material can be estimated using only the electrode located at the edge of the polymer composite material.

Further, the apparatus further includes a data circuit section, and the data circuit section can control the application of the current and the measurement of the voltage.

The data acquisition unit may further include a data acquisition unit, and the data acquisition unit may analyze the acquired data to derive a multiaxial strain value.

A method for measuring a multiaxial strain according to another embodiment of the present invention includes the steps of: (1) pressing a polymer composite material of a multiaxial strain sensor including a polymer composite material and a plurality of electrodes; Applying a current to the polymer composite material through a pair of electrodes of the plurality of electrodes (step 2); Measuring a potential value through at least one pair of electrodes other than the electrode to which the current is applied (step 3); And calculating a resistance component in the polymer composite from the measured potential value (step 4).

Further, it can be repeatedly performed while switching the electrodes of the step 2 and the step 3.

The multi-axis strain sensor system according to the embodiment of the present invention is capable of sensing the direction and the force direction as well as the position and magnitude sensing function of the external pressure applied to the sensor unit. In addition, since the sensor system according to the embodiment of the present invention can be formed in various three-dimensional shapes, there is a great possibility that it can be used as a soft human-machine interface.

1 shows a multi-axis strain sensor system according to an embodiment of the present invention.
FIG. 2 shows an example of proximity pattern measurement.
Fig. 3 shows a method for producing a polymer composite material.
4 shows a sensor section of a multi-axis strain sensor system according to an embodiment of the present invention.
5A shows the pre-deformation structure of the polymer composite.
5B is a photograph of the surface of the polymer composite before the deformation.
FIG. 5C shows the post-deformation structure of the polymer composite material.
5D is a photograph of the surface of the polymer composite after the deformation.
6A shows the arrangement of conductive materials in the composite before deformation of the polymer composite.
FIG. 6B shows the arrangement of the conductive materials in the composite material after deformation of the polymer composite material.
Fig. 7A shows the definitions of R _xx , R _xy resistance components.
Fig. 7B shows the definitions of the resistance components R _yy and R _yx .
8A is a photograph of a sensor of a multi-axis strain sensor system having a hemispherical polymer composite according to an embodiment of the present invention.
FIG. 8B shows the resistivity distribution when an external strain is applied to the hemispherical polymer composite sensor part.
9A is a schematic diagram of an apparatus for analyzing IV characteristics of a polymer composite material.
9B to 9E are graphs showing IV characteristics according to the uniaxial tensile modulus of the polymer composite.
10 is a graph showing electrical resistance according to a weight ratio of a conductive material (MWCNT) in a polymer composite.
11 is a graph showing repeated measurements of the electrical resistivity of the polymer composite material.
12A is a photograph of a polymer composite loaded on a uniaxial tensioning device.
12B is a graph showing the load according to the uniaxial tensile modulus of the polymer composite.
12C is a graph showing the rate of change of resistance according to the uniaxial tensile modulus of the polymer composite.
13A is a photograph of a state in which the polymer composite material is mounted on the uniaxial tensioning device.
Figure 13b shows a modification when the 12.5% of the polymer composite x-component resistivity (ρ _xx) distribution.
Figure 13c shows the time modification is 20.0% of the polymer composite x-component resistivity (ρ _xx) distribution.
13D shows the y component resistivity (p _yy ) distribution when the deformation of the polymer composite is 12.5%.
Figure 13e shows the deformation when the 20.0% of the polymer composite component y resistivity (ρ _yy) distribution.
14A shows a 4-point probe R _yy measurement mode.
14B shows a 4-point probe R _xx measurement mode.
15A is a photograph of a sensor unit of a multi-axis strain sensor system according to an embodiment of the present invention, and a pressing and pressing controller for a vertical push-down cylinder.
15B is a graph showing an actual value of the vertical descent force according to the vertical descent depth after pressure in Fig. 15A and a value estimated by the multi-axial strain sensor measurement method according to another embodiment of the present invention.
15C is a graph comparing positions and actual positions of 49 dropping points estimated by the multi-axis strain sensor measuring method according to another embodiment of the present invention.
FIG. 15D is a mapping of Rxx, Ryy and Rxy components at nine vertical dropping points by the method of measuring a multiaxial strain sensor according to another embodiment of the present invention.
16A is a photograph of a uniaxial tension test controller, a sensor unit, and an electrode connected to the sensor unit.
16B is a graph comparing the tensile length and the actual tensile length of the polymer composite material estimated by the multiaxial strain sensor measurement method according to another embodiment of the present invention.
FIG. 16c is a map of Rxx, Ryy, and Rxy components according to the uniaxial tensile modulus of a polymer composite material in a multi-axial strain sensor measurement method according to another embodiment of the present invention.
17A is a mapping of the R _xx component when the polymer composite is stretched in the x direction by the multiaxial strain measurement method according to another embodiment of the present invention.
17B is a map of the R _yy component when the polymer composite material is stretched in the y direction by the multiaxial strain measurement method according to another embodiment of the present invention.
FIG. 17C is a mapping of the R _xy component when the polymer composite material is stretched in the xy direction by the multiaxial strain measurement method according to another embodiment of the present invention.
18A is a photograph of a polymer composite for a three-dimensional soft interface according to an embodiment of the present invention.
FIG. 18B is a map of a resistivity component for an increase in one-point contact pressure by a method of measuring a multi-axis strain according to another embodiment of the present invention. FIG.
Figure 18c illustrates multi-point contact of a polymer composite for a three-dimensional soft interface according to an embodiment of the present invention.
FIG. 18D is a mapping of a resistivity component to a multi-point contact by a multiaxial strain measurement method according to another embodiment of the present invention. FIG.
FIG. 19A shows the dropping point and the actual dropping point estimated by the multi-axis strain measuring method according to another embodiment of the present invention. FIG.
19B shows a function for robot hand control of a sensor portion of a multi-axis strain sensor system according to an embodiment of the present invention.
FIG. 19C is a photograph of the unfolding and opening operation of a robot hand controlled by the multi-axis strain sensor system according to the embodiment of the present invention. FIG.
Fig. 20 shows a central point of the resistivity in the method for measuring a multiaxial strain according to another embodiment of the present invention.

Hereinafter, preferred embodiments of the present invention will be described with reference to the accompanying drawings. However, the embodiments of the present invention can be modified into various other forms, and the scope of the present invention is not limited to the embodiments described below. Further, the embodiments of the present invention are provided to more fully explain the present invention to those skilled in the art. Accordingly, the shapes and sizes of the elements in the drawings may be exaggerated for clarity of description, and the elements denoted by the same reference numerals in the drawings are the same elements. In the drawings, like reference numerals are used throughout the drawings. In addition, " including " an element throughout the specification does not exclude other elements unless specifically stated to the contrary.

A multi-axis strain sensor system according to an embodiment of the present invention includes a polymer composite material and a sensor unit including a plurality of electrodes disposed at edges of the polymer composite material, wherein a current is applied to a pair of electrodes of the plurality of electrodes, The voltage is measured through a pair of electrodes and a piezoresistive anisotropic strain is sensed.

Hereinafter, a strain sensor system according to the present invention will be described in detail with reference to the drawings.

1 shows a multi-axis strain sensor system according to an embodiment of the present invention.

Referring to FIG. 1, a multi-axis strain sensor system according to an embodiment of the present invention includes a polymer composite 101 and a sensor portion including a plurality of electrodes 102 disposed at the edges of the polymer composite.

The polymer composite may be a composite material of a conductive material and a polymer.

The conductive material 11 may be a conductive material in the form of fibers. That is, it may be a conductive material having a large diameter-to-diameter length, such as a fiber form. In addition, the conductive material may be conductive nanoparticles. For example, the conductive material may be carbon nanotubes or silver nanowires having a long diameter to length, but is not limited thereto. The conductivity or the resistivity of the polymer composite may vary depending on the weight ratio of the conductive material. The resistivity of the conductive material may decrease as the weight ratio of the conductive material increases, and the resistivity may not decrease linearly.

The polymer 12 may be selected from the group consisting of silicone elastomer, polyimide, acrylonitrile butadiene styrene (ABS), polycarbonate (PC), acrylonitrile butadiene styrene / polycarbonate, Monomers and polymers such as terephthalate (PBT), polyethylene terephthalate (PET), polyphenylene sulfide (PPS), polyetheretherketone (PEEK), polydimethylsiloxane (PDMS), flexible polyurethane and natural rubber Particles. ≪ / RTI >

The polymer can serve as a base for the polymer composite. The polymer may be a flexible and flexible material, and may not be limited to a specific shape. Due to such characteristics, it is possible to produce polymer composite materials having complex shapes such as legs and skin.

The mixing and dispersion of the conductive material 11 and the polymer 12 to produce the polymer composite material 101 can be performed through a mechanical mixer.

For example, as shown in FIG. 3, the mechanical dispersion method may be a shear milling method in which a shearing force is generated by using a narrow tube or a relatively high flow to disperse particles, but the present invention is not limited thereto, Other methods of evenly mixing and dispersing the conductive material on the polymer matrix may be applied.

Thereafter, the mixture of the conductive material and the polymer mixed by the above method is injected into the prepared molds 22 and 23, and a polymer composite having a desired shape can be manufactured through the heat treatment.

The polymer composite included in the multi-axis strain sensor system according to the embodiment of the present invention was observed in the uniaxial direction through the scanning electron microscope before and after the tensile test, which is shown in Figs. 5B and 5D.

Referring to FIG. 5B, before the polymer composite material is deformed, it can be seen that the fibrous conductive material is generally irregularly distributed on the surface of the polymer matrix. The above structure is shown in FIG. 5A. When the polymer composite material is uniaxially stretched, tensile deformation of the polymeric composite material causes the conductive material to be stretched along with the stretching of the polymeric composite material irregularly distributed in the polymeric composite material. 5d. FIG. 5C shows the rearrangement of the interior of the polymer composite material.

6A and 6B, the above description is illustrated. Before the deformation of the polymeric composite material 101, the conductive material 11 is disposed in the polymer matrix, and thus the conductive channel 11 'can be formed by the connected conductive material 11'. When the polymer composite is deformed, deformation of the conductive channel occurs and the internal state changes. This results in the rearrangement of the conductive material and the polymer matrix, thereby predicting the possibility of anisotropic electrical properties.

The electrode to which the current is applied and the electrode for measuring the potential value may be sequentially changed.

As shown in FIG. 2, the application of the electric current and the measurement of the electric potential value may use a so-called " adjacent pattern " method, which is closely related to the selection of a pair of current- This method covers all the area of the polymer composite while moving the two electrodes to the side. When the proximity pattern is used, for example, in the sensor portion including 16 electrodes, 256 current application / potential difference measurement patterns are formed, and deformation of the polymer composite material can be detected based on the 256 current application / potential difference measurement patterns.

The resistance change of the polymer composite material can be estimated using only the electrode 102 located at the edge of the polymer composite material.

Conventionally, flexible electrodes were placed on the polymer composite in the transverse and longitudinal directions to sense the amount of strain change at a specific position. However, in the multi-axis strain sensor system according to the embodiment of the present invention, as shown in FIG. 4, a plurality of electrodes are disposed at the edges of the polymer composite material, and through current application and voltage measurement, It may be possible to detect the resistance. Accordingly, the multi-axis strain sensor system according to the embodiment of the present invention does not require a flexible electrode disposed on the surface or at the center of the polymer composite material, and thus it may be possible to manufacture a multi-axis strain sensor system in various shapes.

7A and 7B, a resistance value measured in a direction parallel to a current when a current flows in the x direction is defined as an R _xx component, and a resistance value perpendicular thereto is defined as R _xy . Further, a resistance value measured in a direction parallel to the current when a current flows in the y direction is defined as a R _yy component, and a resistance value perpendicular to the resistance value can be defined as R _yx .

The electrode may include, but is not limited to, at least one of silver paste, silver nanowire-epoxy composite, and liquid metal to reduce surface resistivity with the polymer composite.

8A and 8B, in a multi-axis strain sensor system including a hemispherical polymer composite material according to an embodiment of the present invention, when external pressure is applied to a hemispherical polymer composite material, Component and the xy component resistivity value.

The multi-axis strain sensor system may further include a data circuit unit, and the data circuit unit may control a current application and a voltage measurement.

Referring to Figure 1, The circuit unit may include a multiplexer (MUX), a current driver, and a differential amplifier.

The multiplexer 201 is generally composed of a simple semiconductor device, and an electrode for applying a current and an electrode for measuring a potential value among the plurality of electrodes may be sequentially changed through the multiplexer 201. The multiplexer 201 may apply current to only some of the plurality of connected electrodes.

As shown in FIG. 2, current is applied to some of the plurality of electrodes through the multiplexer, and the potential of the interface of the polymer composite is measured through the remaining electrodes. Then, Current is applied and the potential value corresponding thereto is measured through the remaining electrodes.

The current driver 202 is generally composed of a simple semiconductor device, and may be configured to input a constant current value to the multiplexer.

The differential amplifier 203 is generally made of a simple semiconductor device and can have two input terminals (two input values) and one or two output terminals (one or two output values), and two inputs And amplifies the value input through the terminal at the output terminal. In a multi-axis strain sensor system according to an embodiment of the present invention, the differential amplifier may have a voltage value measured in a polymer composite as an input value. As shown in FIG. 1, a multi-axis strain sensor system according to an embodiment of the present invention includes two voltage output values measured in another pair output from two current input values applied to a pair of electrodes connected to a polymer composite This is the input value applied to the differential amplifier.

The multi-axial strain sensor system may further include a data acquisition unit, and the data acquisition unit may analyze the acquired data to derive a multiaxial strain value.

Referring to Figure 1, The data acquisition unit may include a digital analog converter (DAC), an analog digital converter (ADC), and a data acquisition (DAQ).

The digital-to-analog converter 204 is generally a simple semiconductor device, and is a device for converting a digital value into an analog value. The analog-to-digital converter 205 is generally a simple semiconductor device, and is an apparatus for converting an analog value into a digital value. The data acquisition device 206 is generally comprised of simple semiconductor devices and is responsible for collecting data occurring in a multi-axis strain sensor system according to an embodiment of the present invention. The multi-axis strain sensor system may include a computer 207 connected to the data acquisition device via a USB bus. The multi-axis strain sensor system may control a mechanism that performs complex actions, such as a robotic hand, a tubular robot, or an inflatable adjustment device that is connected to and controllable by the system.

A method for measuring a multiaxial strain according to another embodiment of the present invention includes the steps of: (1) pressing a polymer composite material of a multiaxial strain sensor including a polymer composite material and a plurality of electrodes; Applying a current to the polymer composite material through a pair of electrodes of the plurality of electrodes (step 2); Measuring a potential value through at least one pair of electrodes other than the electrode to which the current is applied (step 3); And calculating a resistance component in the polymer composite from the measured potential value (step 4).

Hereinafter, the multiaxial strain component measuring method according to another embodiment of the present invention will be described in detail for each step.

The " multi-axis strain sensor " may be included in the multi-axis strain sensor system described above, and the description thereof is omitted in order to avoid redundant description

Step 1 of the multiaxial strain measurement method according to another embodiment of the present invention is a step of applying pressure to the polymer composite material of the multiaxial strain sensor including the polymer composite material and the plurality of electrodes.

The multi-axial strain sensor is a sensor for measuring the multi-axial strain of the polymer composite, that is, the strength and the direction of deformation. In the step 1, external pressure and deformation are applied to generate the strain in the polymer composite. At this time, the external pressure may be applied to an inner region of the polymer composite where no electrode is formed

In the step of applying pressure to the polymer composite material, pressure can be applied while simultaneously performing one-point contact, two-point contact or a plurality of contacts on the surface of the polymer composite material, and the area of contact with one point may not be limited.

The contact may be performed through a person's body or through a mechanical device.

The step of applying pressure to the polymer composite material may be performed by stretching or compressing the polymer composite material. The size of the pressure applied to the polymer composite may not be limited.

Step 2 of the multiaxial strain measuring method according to another embodiment of the present invention is a step of applying a current to the polymer composite material through a pair of electrodes of the plurality of electrodes.

A step of applying an electric current to the polymer composite material through a pair of electrodes of the plurality of electrodes to form a potential in the polymer composite material, wherein when the strain is not applied, The potential value when the same amount of current is applied can be compared to confirm the potential value change.

At this time, one end of the electrode is connected to the interface of the polymer composite material, the other end is connected to the multiplexer, and a plurality of electrodes can be connected to surround the interface of the polymer composite material.

Meanwhile, the current applied to the polymer composite material may be generated from a current driver electrically connected to the multiplexer and transferred to the multiplexer, and the multiplexer may apply current to the polymer composite material through the electrode. At this time, the multiplexer selectively applies current to only some of the plurality of electrodes, and can sequentially change the electrodes.

Step 3 of the multiaxial strain measuring method according to another embodiment of the present invention is a step of measuring a potential value through at least one pair of electrodes other than the electrode to which the current is applied.

At this time, the electrode may be a pair of electrodes except a pair of electrodes to which a current is applied. The measured potential value may be output through a multiplexer connected to the plurality of electrodes and may be transmitted to a signal processing device via a differential amplifier electrically connected to the multiplexer in order to amplify the generated potential value .

Step 4 of the multiaxial strain measuring method according to another embodiment of the present invention is a step of calculating a resistance component in the polymer composite from the measured potential value.

The potential difference in the polymer formed by the current applied to the polymer composite can be derived as shown in Equation 1 below using Maxwell brilliantite.

j: current density

σ: Conductivity

u: potential potential

In Equation (1), since the current density is conducted in a direction perpendicular to the surface of the polymer composite material, the current density can be modeled as Equation (2) below.

n: unit outwards normal vector on the surface of the polymer composite.

In order to calculate Equation (2), if Equation (1) is weak formulated, Equation (3) below can be obtained.

Ω: integral area

: 적분 영역의 경계면

: Boundary surface of the integral area

dr: volume differential

dS: area differential

w: test function

In Equation (3), w is an arbitrary test function, and by substituting w = u, Equation (4) below can be obtained.

In Equation (4), the current I applied to the L electrodes located at the interface of the polymer composite material and the voltage V at the corresponding electrode can be expressed by Equation (5) below.

L: Number of electrodes

I _i : Current injection vector

V _j : Voltage potential vector

Equation (5) may mean that the sum of the energies generated when a current is applied to a specific electrode is equal to the amount of potentials that are totally changed in the polymer composite. In Equation (5), it is possible to calculate the influence of a minute change of conductivity when the current is constant by using a perturbation technique on the change in the potential difference.

Assuming that the result obtained by subtracting the value before the micro-change is added after substituting the Equation (6) into the Equation (5) is the same except for the high-order term, the following Equation (7) can be obtained.

When the sensor system of the present invention is in operation, some electrodes are energized, while another electrode is capable of measuring the potential difference. The value of the internal potential difference u generated by the current I _d applied to some electrodes in the above process is u (I _d ), and the value of the internal potential difference u generated by the current I _m applied for measuring the potential difference The value may be u (I _m ), and Equation (7) may be expressed by Equation (8) below.

d: current drive index.

m: voltage measurement index

In Equation (3), if the basis function is used and the test function w used in the weak formulation is replaced by w as shown in Equation (9), the following Equation 10 is obtained .

N: number of vertices constituting the mesh

φ: basis function for finite element method

V _j : Voltage potential vector

S _ij : system matrix

I _i : Current injection vector

Using Equation (10), it is possible to calculate ∇u (I _d ) and ∇u (I _m ) which are formed in the interior of the case where the current I _d or I _m is applied at a specific position and have an initial conductivity σ ₀ .

Assuming that the relationship between the two change amounts is a linear relationship, the change amount? V of the potential measurement value formed by the change amount?? Of conductivity can be easily calculated using Jacobian as shown in Equation (11) below.

The multi-axial strain measuring method according to another embodiment of the present invention can internally calculate the partial differential value of the potential difference in Equation (12) in the process of calculating the gradient value of the internal potential difference.

δσ _ij , _{k :} anisotropy (i, j direction) resistance component of the kth element constituting the conductive composite material (σ)

Through the calculation process described above, the multiaxial strain sensor measurement method according to another embodiment of the present invention can calculate the anisotropic conductivity change (? Ij _{, k} ).

It can be repeatedly performed while switching the electrodes of the step 2 and the step 3.

Among the plurality of electrodes, an electrode for applying a current and an electrode for measuring a potential value are sequentially changed through the multiplexer 31. A current is applied to some electrodes among the plurality of electrodes through the multiplexer and the potential value of the interface of the polymer composite is measured through the remaining electrodes, and then a pair of electrodes other than the pair of electrodes to which the current is applied, And the potential value corresponding thereto is measured through the remaining electrode.

The switching of an electrode for applying a current and an electrode for measuring a potential is referred to as 'switching', and a current is applied to the polymer composite through the switching process, and the potential value at the interface can be repeatedly measured. Through the above process, the anisotropic conductivity change in the conductive polymer composite can be calculated and the multi-axis strain component can be measured.

Production Example 1 - Preparation of a conductive polymer composite mixture containing MWCNT

A silicone rubber (EcoFlex0030, Smooth-On, Inc, USA) was selected as a polymer matrix and a multi-walled carbon in fiber form to manufacture a polymer composite material contained in a sensor part of a multi- A multi-walled carbon nanotube (MWCNT, Hyosung) was selected as a conductive material.

The two materials were stirred for 2 minutes using a planetary centrifugal agitator (PDM-300, EXAKT, Germany). Thereafter, MWCNT was mixed with a three-roll mill (80E, EXAKT, Germany) so that the MWCNT was uniformly distributed on the polymer substrate, thereby preparing a conductive polymer composite mixture having a MWCNT weight ratio of 2.5%.

Production Example 2 - Preparation of a conductive polymer composite mixture containing MWCNT

Was prepared in the same manner as in Preparation Example 1 except that the weight ratio of MWCNT in Production Example 1 was 3.5%.

Production Example 3 - Preparation of a conductive polymer composite mixture containing MWCNT

Was prepared in the same manner as in Preparation Example 1 except that the weight ratio of MWCNT in Production Example 1 was 4.5%.

Production Example 4 - Preparation of a conductive polymer composite mixture containing MWCNT

Was prepared in the same manner as in Production Example 1, except that the weight ratio of MWCNT in Production Example 1 was 5%.

Hereinafter, the mixture in which the MWCNT and the silicone rubber are mixed may be referred to as a MWCNT-silicone rubber mixture.

Production Examples 5 to 8 - Dog bone ( dog bone ) Shaped polymer composites

(Dimension elite, Stratasys, USA) was used as a mold material, and acrylonitrile butadiene styrene (ABS), which can be manufactured at a relatively low cost, was used as a mold material in order to produce a dog- To prepare a mold capable of producing a dog bone-shaped polymer composite.

A release agent (ER200, Mann release technologies, USA) was applied to the surface of a plastic mold manufactured by the above-described three-dimensional printing apparatus, thereby facilitating the separation of the composite material from the mold.

The MWCNT-silicone rubber mixture prepared according to Preparation Examples 1 to 4 was pressurized with compressed air to a mold capable of producing the dog bone-shaped composite material prepared above, and the mixture was injected into the mold prepared above And heat-treated at 70 ° C for about 1 hour in an atmospheric environment using a convection oven (OF-02, Jeiotech, South Korea).

After the heat treatment was performed, the dog bone-shaped polymer composite material was separated from the mold so that the weight of the MWCNT was 2.5%, 3.5%, 4.5%, and 5.0%, and the dog bone MWCNT- . The polymer composite material is characterized in that the dog-shaped polymer composite material has a structure suitable for being fixed to a tensile tester.

Production Examples 9 to 12 - Production of a square pipe-shaped polymer composite

The square-pipe-shaped polymer composite material is characterized by having one long shape in the axial direction. In order to produce the above-mentioned polymer composite material, acrylonitrile butadiene styrene was used as a material, and a three-dimensional printing device (Dimension elite, Stratasys, USA) A hollow space and a mold having the MWCNT-silicone rubber mixture injection part were prepared.

The weight of the MWCNT was 2.5%, 3.5%, 4.5%, and 5.0%, and was about 5 mm in width, about 3 mm in length, and about 3 mm in length by using the same manufacturing processes as those of Production Examples 5 to 8 except that the above- Shaped polymer composite having a dimension of about 10 mm was prepared.

Production Example 13 - Production of a square-shaped polymer composite

The square-shaped polymer composite material is characterized by having a wide main surface. In order to produce the above-mentioned polymer composite material, acrylonitrile butadiene styrene was used as a material, and a three-dimensional printing device (Dimension elite, Stratasys, USA) A hollow space and a mold having the MWCNT-silicone rubber mixture injection part were prepared.

The same procedure as in Production Example 5 was carried out except that the above-mentioned mold was used. Thus, a square-shaped polymer composite material having a MWCNT weight of 2.5%, a width of about 50 mm, a length of about 30 mm and a thickness of about 5 mm .

Production Example 14 - Production of polymer composite for three-dimensional soft interface

In order to fabricate a polymer composite in which the hemispherical polymer composite is uniaxially stretched, a mold manufactured through a three - dimensional printing apparatus is prepared.

The MWCNT-silicone rubber composite prepared in Preparation Example 1 was injected into the prepared mold, and then a hemispherical polymer composite having dimensions of about 70 mm in width and about 150 mm in length was prepared on the basis of the respective central axes through the same procedure as in Production Example 5 a polymer composite material having a shape elongated in the y-axis direction was prepared.

Example 1 - The sensor part  Have Multiple axes  Strain sensor system

In order to fabricate a multi-axis strain sensor system having a square-shaped sensor unit, sixteen silver paste electrodes were attached to the edges of the square-shaped polymer composite material prepared in Production Example 10, and a square-shaped sensor unit was fabricated.

The circuit unit and the data acquisition unit are connected to each other through a wire connected to the electrode of the sensor unit manufactured as described above. The circuit portion includes a multiplexer, a current driving device, and a differential amplifier. The data acquisition unit includes a digital-to-analog converter, an analog-to-digital converter, and a data acquisition device. It also includes a computer connected to the data collection device via USB.

A square plate type multi-axis strain sensor system according to an embodiment of the present invention uses cDAQ 9174 (National Instruments, USA) as a data collection device and operates at a sampling frequency of 30 kHz.

In the case of using the proximity pattern, the data acquisition time of about 0.025 seconds is required when the multi-axis strain sensor system having the frequency bandwidth of 10 kHz is used for the 256 current application / potential difference measurement patterns by 16 electrodes. The acquired data is processed by a method for measuring a multi-axis strain according to another embodiment of the present invention, and it takes less than 0.1 second to be implemented with multi-axis strain.

Example 2 - Three-dimensional soft interface The sensor part  Have Multiple axes  Strain sensor system

In order to manufacture a multi-axis strain sensor system having a three-dimensional soft interface sensor unit, sixteen silver paste electrodes were attached to the edge of the polymer composite prepared in Production Example 14, and a square plane sensor unit was fabricated.

The circuit unit and the data acquisition unit are connected to each other through a wire connected to the electrode of the sensor unit manufactured as described above. The circuit portion includes a multiplexer, a current driving device, and a differential amplifier. The data acquisition unit includes a digital-to-analog converter, an analog-to-digital converter, and a data acquisition device. It also includes a computer connected to the data collection device via USB.

A multi-axis strain sensor system with a three-dimensional soft interface sensor according to an embodiment of the present invention uses cDAQ 9174 (National Instruments, USA) as a data acquisition device and operates at a sampling frequency of 30 kHz.

In the case of using the proximity pattern, the data acquisition time of about 0.025 seconds is required when the multi-axis strain sensor system having the frequency bandwidth of 10 kHz is used for the 256 current application / potential difference measurement patterns by 16 electrodes. The acquired data is processed by a method for measuring a multi-axis strain according to another embodiment of the present invention, and it takes less than 0.1 second to be implemented with multi-axis strain.

Experimental Example 1 Measurement of Resistance Change According to MWCNT-Silicone Rubber Composite Tension

As shown in FIG. 12A, the dog bone MWCNT-silicone rubber composite prepared according to Production Examples 5 to 8 was subjected to 0 to 40% tensile using a hand-made tensioner. At this time, The load is shown in Fig. 12B.

As shown in FIG. 12B, as the weight ratio of MWCNT in the MWCNT-silicone rubber composite increases, the load applied to the same tensile ratio increases. The mechanical stiffness increased from 76 kPa to 166 kPa as the weight ratio of MWCNT increased to 2.5%, 3.5%, 4.5% and 5%. The mechanical stiffness of 166 kPa is low enough to provide the flexibility and softness required for direct human use.

The resistivity of the polymer composite material was measured according to the degree of deformation of the polymer composite material while simultaneously performing current application and voltage measurement through the electrode connected to the edge of the polymer composite material. The result is shown in FIG. 12c.

As shown in FIG. 12C, the rate of change of the resistance value for the same tensile modulus, that is, the resistance resistance, was found to be larger as the weight ratio of MWCNT in the MWCNT-silicone rubber composite was smaller. That is, the smaller the weight ratio of MWCNT in the MWCNT-silicone rubber composite is, the greater the sensitivity of the resistance against external strain is.

The sensitivities of the MWCNT-silicone rubber composites prepared according to Preparation Examples 5 to 8 were 1.61, 1.12, 0.91, 0.67. Since the polymer composite material used in the sensor portion of the multi-axis strain sensor system according to the embodiment of the present invention should be flexible and high in resistance to pressure resistance, the polymer composite material having MWCNT weight ratio of 2.5% according to Production Example 1 having low rigidity and high sensitivity Polymer composites prepared using materials may be suitable.

Experimental Example 2 Measurement of Resistance and Electrical Properties of Square Pipe Type MWCNT-Silicone Rubber Composite

In order to confirm the change of the resistance value according to the weight ratio of the conductive material MWCNT in the polymer composite material, the square pipe-type polymer composite material prepared in Production Examples 9 to 12 was prepared. As shown in the schematic diagram of FIG. The paste electrode 102 was attached to both ends of the polymer composite material 101 in the longitudinal direction of the square pipe type and the electric wire connected to the electrode was connected to a semiconductor parameter analyzer 4155A (HP, USA) to measure an electric resistance value according to the weight ratio of MWCNT And the results are shown in Fig.

As a result, it was confirmed that the resistance value decreased as the weight ratio of MWCNT gradually increased from 2.5% to 3.5%, 4.5% and 5.0%.

The resistance value of the polymer composite according to Production Example 9 in which the weight ratio of MWCNT was 2.5% was measured 20 times and the results are shown in FIG. The measured results showed an average value of about 263 ohm-mm and a standard deviation of about 16.7% (± 43.8 ohm-mm) with respect to the average.

As shown in the schematic diagram of Fig. 14 (a), the square-pipe-type polymer composite produced in Production Example 9 was attached with silver paste electrodes at both ends in the longitudinal direction of a square-shaped polymer composite, and wires were connected to a semiconductor parameter analyzer 4155A , HP, USA) To measure the IV relationship with 0 to 80% tensile of the polymer composite, and the results are shown in FIGS. 9B to 9E.

As a result of the measurement of the I-V relationship, it was confirmed that the current-voltage exhibited a linear relationship, that is, an ohmic behavior, regardless of the tensile ratio.

Experimental Example 3 - Resistance component measurement according to tensile strength of MWCNT-silicone rubber composite

A square-planar polymer composite material having a weight ratio of 2.5% according to Production Example 13 was prepared. Both ends of the polymer composite material were fixed to the device and uniaxial tensile strength was 10 to 20%. For the above experiment, the polymer composite was mounted on the uniaxial tensioning device as shown in FIG. 13A, and tensile was performed in the y direction. In order to measure the resistivity components in the x and y directions of the composite plane according to the tensile, 140 divided areas divided into quadrangles are allocated, and the divided areas are divided into the four-point probe device 4 shown in Figs. 14A and 14B point probe, Dasol engineering, South Korea). As shown in Figs. 14A and 14B, the R _yy mode measurement was performed by the method shown in Fig. 14A, and the R _xx mode measurement was performed by the method shown in Fig. 14B.

13A to 13E, when the deformation in the y direction was 12.5% and 20%, ρ _xx increased by 4.73% and 12.65%, respectively, and the deformation in the x direction was 12.5% and 20% Ρ _yy increased by 8.58% and 24.02%, respectively. When the polymer composite was stretched in the y direction, the change in resistivity ρ _yy was about two times higher than the change in resistivity ρ _xx .

The above results indicate that the polymer composite included in the multi-axis strain sensor system according to the embodiment of the present invention exhibits a change in resistivity anisotropy due to uniaxial deformation. It can be considered that the electrically conductive material (MWCNT) in the form of a long, thin fiber is rearranged to extend by external deformation, so that the channel of the electron movement is changed and the electrical characteristics in the direction perpendicular to the direction of extension are changed.

Experimental Example 4 - Multiple axes  Strain sensor system vertical Squeeze  exam( normal indentation  test)

A multi-axis strain sensor system having a square plane sensor portion prepared by Example 1 was used for the push-down test. 15A, for this experiment, cylindrical indentor made of ABS plastic having a diameter of 5 mm was used. After an indenter was placed on the center of the polymer composite, the indenter was contacted with the polymer composite, .

Accordingly, the actual pressing force and the indentation depth of the indentor and the multi-axis strain sensor system having the square plane sensor unit according to the embodiment of the present invention were used to estimate the pressing force and the indentation depth, and the results are shown in FIG. 15B.

As shown in FIG. 15B, an error of about 0.61 ± 0.62 N was shown when a downward force of 9 N was applied to one push-down point. Thus, it was confirmed that the estimated depression force and depression depth have similar results by using the actually applied depression force and the indentation depth of the indentor and the multi-axis strain sensor system having the square plane sensor unit according to the embodiment of the present invention.

In addition, indentation was performed at 49 points in the same manner as above at intervals of 5 mm in the area of 40 mm long and 40 mm wide on the upper surface of the polymer composite of the square planar type polymer composite, The results are shown in Fig. 15C.

As a result of the measurement, the difference between the predicted contact position and the actual contact position with respect to the 49 individual contacts tends to be greater between the actual value and the estimated value at a position farther from the central region of the sensor unit. Using the multi-axis strain sensor system with a square planar sensor unit according to the example, the estimated error of the estimated drop point was measured to be 1.88 ± 0.95 mm.

Referring to FIG. 15D, it can be seen that anisotropic resistance distributions are shown for nine different depression points out of the 49 depression points. As a result, the results of vertical indentation test of the polymer composite surface showed similar resistivity changes along the x and y directions.

Experimental Example 5 - Multiple axes  Strain sensor system y direction  Tensile detection test

In a multiaxial strain sensor system having a square plane sensor portion prepared according to Example 1, a rectangular polymer composite material was mounted on a manually prepared tensile tester and subjected to a tensile test as shown in FIG. 16A.

Referring to FIG. 16B, it can be confirmed that an error of about 1.15 ± 0.64 mm can be estimated when y-directional tensile is applied up to 16 mm.

Referring to FIG. 16C, it can be seen that the resistivity in both the x and y directions increases at a tensile ratio of 0 to 50%. The resistivity distribution (ρ _xx ) in the X direction increased by about 10% on average and the resistivity distribution (ρ _yy ) in the y direction increased by 20% on average. The above results indicate that the multi-axis strain sensor system according to the embodiment of the present invention can distinguish the direction of the anisotropic resistivity distribution and the tensile ratio.

Experimental Example 6 - Multiple axes  Strain sensor system 3 direction detection test

Axis direction (? = 0 °), the y-axis (? = 0 °), and the diagonal direction (?) With respect to the x direction as the reference of the square-planar polymer composite material of the multiaxial strain sensor system having the square- = 0 [deg.]), And the results are shown in Figs. 17A to 17C.

Referring to FIG. 17A, it can be seen that when the polymer composite is stretched along the x-axis (? = 0), the x-axis specific resistance (? _Xx ) distribution is increased. Referring to FIG. 17B, it can be seen that the resistivity (ρ _yy ) distribution in the y-axis increases when the polymer composite is stretched along the y-axis (θ = 90 °). Referring to FIG. 17C, it can be confirmed that the shear resistivity (rho _xy ) distribution increases when the polymer composite is pulled in the diagonal direction (? = 45 占). The above results indicate that the polymer composite stretching direction of the sensor part included in the multi-axis strain sensor system according to the embodiment of the present invention can be identified.

Experimental Example 7 - Multiple axes  Strain sensor system 3D soft interface experiment

In the multiaxial strain sensor system having a three-dimensional soft interface prepared according to Example 2, the resistivity distribution according to the increase in the descending force of the point contacted with the polymer composite material was measured and shown in Figs. 18A and 18B.

Referring to FIG. 18B, it can be seen that the multi-axial strain sensor system according to the embodiment of the present invention can distinguish the difference in contact pressure at one point contact.

Figure 18c illustrates multi-point contact of a polymer composite for a three-dimensional soft interface according to an embodiment of the present invention. Referring to FIG. 18D, the first five columns show the distribution of the resistivity variation as each contact location is individually depressed. On the other hand, the multi-touch test results of the last two items indicate the function of the sensor when sensing multiple pressure patterns

19A, the sensor part of the multi-axial strain sensor system having a polymer composite for a three-dimensional soft interface is subjected to a contact position estimation experiment at intervals of 10 mm in the region of 10 to 60 mm in the x direction and at intervals of 10 mm in the region of 25 to 125 mm in the y direction And the actual contact position and estimated position error were 4.80 ± 3.05 mm.

Figure 19b shows a robot hand (BH8-262, Barrett Technology, USA) connected to the multi-axis strain sensor system. Since the robot hand has three fingers, the sensor unit of the multi-axis strain sensor system having the three-dimensional soft interface sets the same three control points. Specifically, as shown in Fig. 19B, the sensor portion was divided into three portions, and the respective contact positions were calculated.

Referring to FIG. 19C, the average value of the change in resistivity obtained in the divided area assigned to each finger was used to control the bending speed of the robot finger assigned to each zone. Also, the expansion angle of the robot finger was calculated by deriving the midpoint of the resistivity values of the three zones. The center point of the resistivity value was calculated with reference to the following expression (13).

Referring to FIG. 20, the calculation process of Equation (13) is shown and described.

The operation of the multi-axis strain sensor system having the polymer composite for a three-dimensional soft interface according to the embodiment of the present invention and the movement of the robot hand were performed with a time gap of 0.1 second. The time gap is the time required to calculate the resistivity distribution, the data acquisition, and the resistivity distribution.

A multi-axis strain sensor system having a polymer composite for a three-dimensional soft interface according to an embodiment of the present invention can be manufactured in various three-dimensional shapes. Polymer composites for 3D soft interface can be fabricated, for example, by wrapping the outer surface of a tubular robot or an inflatable adjustment device.

101: Polymer composite
102: electrode
201: Multiplexer
202: Current Driver
203: Differential Amplifier
204: digital to analog converter (DAC)
205: analog to digital converter (ADC)
206: data acquisition (DAQ)
207: Computer
11: Conductive material
11 ': connected conductive material
12: Polymers
13: Mechanical mixer
101: Polymer composite
21: 3D printing device
22: hemispherical polymer composite mold
23: square planar polymer composite mold

Claims (8)

And a sensor unit including a polymer composite material and a plurality of electrodes disposed at the edges of the polymer composite material, wherein a current is applied to a pair of electrodes of the plurality of electrodes and a voltage is measured through a pair of the remaining electrodes, A method of measuring a pressure resistance anisotropic resistance component of a polymer composite with respect to a deformation of a polymer composite and measuring a deformation component in a first direction and a second direction along a surface of the polymer composite with respect to deformation of the polymer composite, A multi - axis strain sensor system for estimating resistance distribution using only electrodes.
The method according to claim 1,
Wherein the electrode to which the current is applied and the electrode to measure the potential value are sequentially changed.
delete delete The method according to claim 1,
Wherein the multi-axis strain sensor system further comprises a data circuit section, wherein the data circuit section controls the application of a current and the measurement of a voltage.
The method according to claim 1,
Wherein the multi-axis strain sensor system further comprises a data acquisition unit, wherein the data acquisition unit analyzes the acquired data to derive a multi-axis strain value.
(Step 1) of applying pressure to the polymer composite of the multiaxial strain sensor of the multiaxial strain sensor system according to claim 1, comprising a polymer composite and a plurality of electrodes;
Applying a current to the polymer composite material through a pair of electrodes of the plurality of electrodes (step 2);
Measuring a potential value through at least one pair of electrodes other than the electrode to which the current is applied (step 3); And
And calculating a resistance component in the polymer composite from the measured potential value (step 4).
8. The method of claim 7,
And repeating the operation while switching the electrodes of the step 2 and the step 3.

Images