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WO2019129387A1 - Structured composites useful as low force sensors - Google Patents

Structured composites useful as low force sensors Download PDF

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Publication number
WO2019129387A1
WO2019129387A1 PCT/EP2018/050002 EP2018050002W WO2019129387A1 WO 2019129387 A1 WO2019129387 A1 WO 2019129387A1 EP 2018050002 W EP2018050002 W EP 2018050002W WO 2019129387 A1 WO2019129387 A1 WO 2019129387A1
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WO
WIPO (PCT)
Prior art keywords
accordance
composite material
film
volume fraction
conductive
Prior art date
Application number
PCT/EP2018/050002
Other languages
French (fr)
Inventor
Mathieu TAUBAN
Mickaël PRUVOST
Annie Colin
Philippe Poulin
Lise Trouillet-Fonti
Olivier SANSEAU
Original Assignee
Rhodia Operations
Ecole Superieure De Physique Et De Chimie Industrielles De La Ville De Paris
Le Centre National De La Recherche Scientifique
Priority date (The priority date is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the date listed.)
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Publication date
Application filed by Rhodia Operations, Ecole Superieure De Physique Et De Chimie Industrielles De La Ville De Paris, Le Centre National De La Recherche Scientifique filed Critical Rhodia Operations
Priority to PCT/EP2018/050002 priority Critical patent/WO2019129387A1/en
Priority to JP2020536619A priority patent/JP7026238B2/en
Priority to CN201880090630.9A priority patent/CN112004874B/en
Priority to PCT/EP2018/059956 priority patent/WO2019129390A1/en
Priority to EP18716646.7A priority patent/EP3735438A1/en
Priority to PCT/EP2018/059957 priority patent/WO2019129391A1/en
Priority to KR1020207022277A priority patent/KR102560957B1/en
Priority to BR112020013390-6A priority patent/BR112020013390A2/en
Priority to US16/958,882 priority patent/US20200337569A1/en
Publication of WO2019129387A1 publication Critical patent/WO2019129387A1/en

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    • CCHEMISTRY; METALLURGY
    • C08ORGANIC MACROMOLECULAR COMPOUNDS; THEIR PREPARATION OR CHEMICAL WORKING-UP; COMPOSITIONS BASED THEREON
    • C08JWORKING-UP; GENERAL PROCESSES OF COMPOUNDING; AFTER-TREATMENT NOT COVERED BY SUBCLASSES C08B, C08C, C08F, C08G or C08H
    • C08J9/00Working-up of macromolecular substances to porous or cellular articles or materials; After-treatment thereof
    • C08J9/28Working-up of macromolecular substances to porous or cellular articles or materials; After-treatment thereof by elimination of a liquid phase from a macromolecular composition or article, e.g. drying of coagulum
    • C08J9/283Working-up of macromolecular substances to porous or cellular articles or materials; After-treatment thereof by elimination of a liquid phase from a macromolecular composition or article, e.g. drying of coagulum a discontinuous liquid phase emulsified in a continuous macromolecular phase
    • BPERFORMING OPERATIONS; TRANSPORTING
    • B32LAYERED PRODUCTS
    • B32BLAYERED PRODUCTS, i.e. PRODUCTS BUILT-UP OF STRATA OF FLAT OR NON-FLAT, e.g. CELLULAR OR HONEYCOMB, FORM
    • B32B5/00Layered products characterised by the non- homogeneity or physical structure, i.e. comprising a fibrous, filamentary, particulate or foam layer; Layered products characterised by having a layer differing constitutionally or physically in different parts
    • B32B5/18Layered products characterised by the non- homogeneity or physical structure, i.e. comprising a fibrous, filamentary, particulate or foam layer; Layered products characterised by having a layer differing constitutionally or physically in different parts characterised by features of a layer of foamed material
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    • C08J5/00Manufacture of articles or shaped materials containing macromolecular substances
    • C08J5/18Manufacture of films or sheets
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    • C08J7/00Chemical treatment or coating of shaped articles made of macromolecular substances
    • C08J7/04Coating
    • C08J7/0427Coating with only one layer of a composition containing a polymer binder
    • CCHEMISTRY; METALLURGY
    • C08ORGANIC MACROMOLECULAR COMPOUNDS; THEIR PREPARATION OR CHEMICAL WORKING-UP; COMPOSITIONS BASED THEREON
    • C08JWORKING-UP; GENERAL PROCESSES OF COMPOUNDING; AFTER-TREATMENT NOT COVERED BY SUBCLASSES C08B, C08C, C08F, C08G or C08H
    • C08J7/00Chemical treatment or coating of shaped articles made of macromolecular substances
    • C08J7/04Coating
    • C08J7/044Forming conductive coatings; Forming coatings having anti-static properties
    • CCHEMISTRY; METALLURGY
    • C08ORGANIC MACROMOLECULAR COMPOUNDS; THEIR PREPARATION OR CHEMICAL WORKING-UP; COMPOSITIONS BASED THEREON
    • C08JWORKING-UP; GENERAL PROCESSES OF COMPOUNDING; AFTER-TREATMENT NOT COVERED BY SUBCLASSES C08B, C08C, C08F, C08G or C08H
    • C08J9/00Working-up of macromolecular substances to porous or cellular articles or materials; After-treatment thereof
    • C08J9/0061Working-up of macromolecular substances to porous or cellular articles or materials; After-treatment thereof characterized by the use of several polymeric components
    • CCHEMISTRY; METALLURGY
    • C08ORGANIC MACROMOLECULAR COMPOUNDS; THEIR PREPARATION OR CHEMICAL WORKING-UP; COMPOSITIONS BASED THEREON
    • C08JWORKING-UP; GENERAL PROCESSES OF COMPOUNDING; AFTER-TREATMENT NOT COVERED BY SUBCLASSES C08B, C08C, C08F, C08G or C08H
    • C08J9/00Working-up of macromolecular substances to porous or cellular articles or materials; After-treatment thereof
    • C08J9/0066Use of inorganic compounding ingredients
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    • C08ORGANIC MACROMOLECULAR COMPOUNDS; THEIR PREPARATION OR CHEMICAL WORKING-UP; COMPOSITIONS BASED THEREON
    • C08JWORKING-UP; GENERAL PROCESSES OF COMPOUNDING; AFTER-TREATMENT NOT COVERED BY SUBCLASSES C08B, C08C, C08F, C08G or C08H
    • C08J9/00Working-up of macromolecular substances to porous or cellular articles or materials; After-treatment thereof
    • C08J9/009Use of pretreated compounding ingredients
    • GPHYSICS
    • G01MEASURING; TESTING
    • G01LMEASURING FORCE, STRESS, TORQUE, WORK, MECHANICAL POWER, MECHANICAL EFFICIENCY, OR FLUID PRESSURE
    • G01L9/00Measuring steady of quasi-steady pressure of fluid or fluent solid material by electric or magnetic pressure-sensitive elements; Transmitting or indicating the displacement of mechanical pressure-sensitive elements, used to measure the steady or quasi-steady pressure of a fluid or fluent solid material, by electric or magnetic means
    • G01L9/0026Transmitting or indicating the displacement of flexible, deformable tubes by electric, electromechanical, magnetic or electromagnetic means
    • G01L9/003Transmitting or indicating the displacement of flexible, deformable tubes by electric, electromechanical, magnetic or electromagnetic means using variations in capacitance
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    • C08ORGANIC MACROMOLECULAR COMPOUNDS; THEIR PREPARATION OR CHEMICAL WORKING-UP; COMPOSITIONS BASED THEREON
    • C08JWORKING-UP; GENERAL PROCESSES OF COMPOUNDING; AFTER-TREATMENT NOT COVERED BY SUBCLASSES C08B, C08C, C08F, C08G or C08H
    • C08J2201/00Foams characterised by the foaming process
    • C08J2201/02Foams characterised by the foaming process characterised by mechanical pre- or post-treatments
    • C08J2201/026Crosslinking before of after foaming
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    • C08JWORKING-UP; GENERAL PROCESSES OF COMPOUNDING; AFTER-TREATMENT NOT COVERED BY SUBCLASSES C08B, C08C, C08F, C08G or C08H
    • C08J2201/00Foams characterised by the foaming process
    • C08J2201/04Foams characterised by the foaming process characterised by the elimination of a liquid or solid component, e.g. precipitation, leaching out, evaporation
    • C08J2201/05Elimination by evaporation or heat degradation of a liquid phase
    • C08J2201/0504Elimination by evaporation or heat degradation of a liquid phase the liquid phase being aqueous
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    • C08J2205/00Foams characterised by their properties
    • C08J2205/04Foams characterised by their properties characterised by the foam pores
    • C08J2205/044Micropores, i.e. average diameter being between 0,1 micrometer and 0,1 millimeter
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    • C08J2205/00Foams characterised by their properties
    • C08J2205/04Foams characterised by their properties characterised by the foam pores
    • C08J2205/052Closed cells, i.e. more than 50% of the pores are closed
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    • C08JWORKING-UP; GENERAL PROCESSES OF COMPOUNDING; AFTER-TREATMENT NOT COVERED BY SUBCLASSES C08B, C08C, C08F, C08G or C08H
    • C08J2205/00Foams characterised by their properties
    • C08J2205/06Flexible foams
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    • C08JWORKING-UP; GENERAL PROCESSES OF COMPOUNDING; AFTER-TREATMENT NOT COVERED BY SUBCLASSES C08B, C08C, C08F, C08G or C08H
    • C08J2207/00Foams characterised by their intended use
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    • C08J2367/00Characterised by the use of polyesters obtained by reactions forming a carboxylic ester link in the main chain; Derivatives of such polymers
    • C08J2367/02Polyesters derived from dicarboxylic acids and dihydroxy compounds
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    • C08ORGANIC MACROMOLECULAR COMPOUNDS; THEIR PREPARATION OR CHEMICAL WORKING-UP; COMPOSITIONS BASED THEREON
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    • C08J2383/00Characterised by the use of macromolecular compounds obtained by reactions forming in the main chain of the macromolecule a linkage containing silicon with or without sulfur, nitrogen, oxygen, or carbon only; Derivatives of such polymers
    • C08J2383/04Polysiloxanes
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    • C08J2483/00Characterised by the use of macromolecular compounds obtained by reactions forming in the main chain of the macromolecule a linkage containing silicon with or without sulfur, nitrogen, oxygen, or carbon only; Derivatives of such polymers
    • C08J2483/04Polysiloxanes

Definitions

  • the present invention relates to composite materials comprising a porous siloxane polymer matrix with a closed porosity volume fraction and a conductive or semiconductive (hereinafter jointly referred to as conductive filler) carbonaceous filler substantially present in said closed porosity volume fraction of the matrix.
  • Pressure sensors have attracted much attention in the recent past due to their potential for a variety of different applications. Especially the demand for pressure sensors with high sensitivity in low pressure regions is very high, which systems are needed i.a. for healthcare and medical diagnosis systems as well as in electronic systems, in particular so called e-skin systems.
  • Pressure sensing devices are typically categorized into three types,
  • Piezoresistive devices use the change in conductivity upon application of external pressure.
  • Piezoelectric devices use the piezoelectric effect, i.e. the generation of an electric charge in a material upon application of pressure.
  • the sensitivity of a piezoielectric device is limited by the physical properties of the piezoelectric substance at the origin of the effect.
  • Piezocapacitive sensors make use of the capacitance change occuring in reaction to the aaplication of pressure and their sensitivity is not theoretically limited.
  • the change of capacitance can be a consequence of the distance of two electrodes of the system forming a capacitor changing in reaction to the application of pressure or due to the modification of the equivalent dielectric constant of the dielectric material sandwiched between two electrodes under the application of pressure.
  • piezocapacitive sensors offer some advantages such as low power consumption and better reproducability. Compared to piezoelectric devices piezocapacitive sensors are easier to process and easier to shape into different forms. Moreover, they do not require a poling or stretching. [0005] The magnitude of the capacitance change is determined by the change in dielectric constant, the thickness of a dielectric layer and the surface area of an electrode.
  • Micro- or nano-structures have been suggested in such devices to improve the sensitivity in particular in the low pressure range.
  • this requires usually complex and expensive fabrication processes.
  • Porous films are prepared by using a siloxane elastomer material and water droplets without any additives. Polydimethylsiloxane is used as a base material and water droplets are selected as dispersion substance.
  • a solution of PDMS prepolymers , mixed with a curing agent, and water is stirred in a container. Through the stirring process, micro-droplets of water are uniformly dispersed in the PDMS solution due to the insolubility of water.
  • the solution thus obtained is placed between two glass substrates and thereafter the solution is cured. During curing, the water evaporates and a polymerized porous PDMS film having micro-pores where water was initially present is obtained. This film having a thickness of appr. 100 pm forms the dielectric layer of a capacitive type pressure sensor.
  • Elastomeric force sensitive resistors are made from a porous matrix of PDMS filled with carbon black.
  • the PDMS matrix has the form of a sponge and is obtained using a sugar scaffold .
  • Sugar cubes are placed in a dish with PDMS precursors and left for one hour to become saturated with the PDMS. The cubes are then cured, excess PDMS is trimmed away and the cubes are put in a beaker with distilled water to dissolve the sugar.
  • the structure thus obtained is the inverse matrix of the sugar cube in which voids are distributed and oriented in a random configuration.
  • a suspension of carbon black in water is added dropwise to the water saturated sponge thereby creating a high concentration of carbon within the open porosity volume fraction of the sponge.
  • the sponge is left to dry and a thin layer of PDMS is coated thereon and cured to seal the carbon inside the sponge.
  • the pore walls are lined with carbon. Upon application of pressure, the carbon-black lined pore walls come into contact, thereby increasing the number of carbon-carbon connections and the pores become conducting.
  • a further object of the present invention are films comprising the
  • composite material in accordance with claim 1 as well as substrates coated with a film made of the composite material in accordance with the present invention.
  • a porous matrix material comprising a siloxane polymer, comprising a closed porosity volume fraction, and, optionally, an open porosity volume fraction, and
  • Porous materials are usually characterized by their porosity.
  • Porosity or void fraction is a measure of the void (i.e. "empty") spaces in a material, and is the fraction of the volume of voids over the total volume, between 0 and 1 , or as a percentage between 0% and 100%.
  • the apparent porosity or open porosity is a fraction of the porosity and is the volume of the open pores, into which a liquid or gas can penetrate, as a percentage of the total volume of the material.
  • Non-interconnected voids trapped in the solid phase are not part of the open porosity volume fraction; they are part of the closed porosity volume fraction. This fraction also includes any kind of closed pores in the material.
  • the porous matrix material of the composite materials in accordance with the present invention comprises a closed porosity volume fraction, in which a substantial part of the conductive or semiconductive filler is present.
  • the closed porosity volume fraction is preferably equal to or greater than the open porosity volume fraction of the material, i.e. the volume of the pores which form the closed porosity volume fraction is preferably at least equal to or greater than the volume of the pores forming the open porosity volume fraction (the ratio of both pore volume fractions thus preferably is at least 1).
  • the ratio of the closed porosity volume to the open porosity volume is in the range of from 1 :1 to 100:1 , preferably in the range of from 1.5:1 to 50:1
  • the open porosity volume fraction of a porous material can be deternined by gas displacement pycnometry, a technique known to the skilled person.
  • This technique uses the gas displacement method to measure volume accurately.
  • An inert gas, usually He, is used as the displacement gas.
  • a sample of known weight is sealed in a compartment of the measuring device having a known volume. Then He is allowed to flow into the chamber through an inlet valve until equilibrium is reached, i.e. until the pressure is constant. Then the inlet valve is closed and an outlet valve to a second chamber of precisely known volume is opened.
  • V s the volume displaced by the sample
  • V c the known volume of the sample cell
  • compartment cell is P e , the volume displaced by the sample can be calculated as
  • Vs Vc - Vr (Pe/(Pa-Pe))
  • the displaced or pycnometer volume Vs reflects the volume of the solid part of the porous sample (which is referred to herein as as theoretical volume) plus the volume of the closed pores.
  • Theoretical volume can be obtained from the theoretical density of a solid sample without pores, which is usually known for most materials or can be easily determined. Subtracting the theoretical volume from the pycnometer volume yields the volume of the closed pores.
  • the bulk volume of the porous sample is the geometric volume of the
  • the volume of the open pores can be obtained by subtracting the theoretical volume and the closed pore volume (obtained as explained above) from the bulk (geometrical) volume of the sample.
  • the open porosity volume fraction is obtained by dividing the volume of the closed pores by the bulk volume.
  • the open porosity volume fraction can be obtained in an analogous manner. The ratio of both fractions is then obtained by simply dividing the closed pore volume fraction by the open porosity volume fraction.
  • the total porosity of a porous sample can also be obtained by dividing the bulk density by the theoretical density and subtracting the value from 1.
  • a sample having a theoretical volume of of 2 cm 3 and a pycnometer volume of 3 cm 3 has a closed porosity volume fraction of 1 cm 3 (obtained by subtracting the theoretical volume from the pycnometer volume). If the porous sample has a geometric (bulk) volume of 4 cm 3 , the total porosity, based on the bulk volume, is 2/4 or 0.5.
  • the closed porosity volume fraction, relative to the bulk volume, in this case is 0,25, relative to the total pore volume of the sample, 0.5. This yields a ratio closed porosity volume fraction/open porosity volume fraction of 1.
  • the pycnometer volume is 3,5 cm 3
  • the volume of the closed pores is 1 ,5 cm 3 which translates into 37,5 % , based on the bulk volume or 75 %, based on the total pore volume.
  • the ratio closed porosity volume fraction to open porosity volume fraction is 3:1.
  • present invention is a siloxane polymer.
  • Siloxane polymers or polysiloxanes also known as silicones, are polymers that include an inert, synthetic compound made up of repeating units of siloxane, frequently combined with carbon or hydrogen or both. They are typically heat-resistant and rubber-like.
  • a siloxane is a functional group in organosilicon chemistry with the -Si-O- Si-linkage.
  • the word siloxane is derived from the words silicon, oxygen and alkane.
  • Siloxane materials may be composed of several types of so called siloxide groups, depending on the number of Si-0 bonds: M-units represented by general structural element R3S1O0.5, D-units by the general structural element R2S1O and T-units represented by the general structural element RS1O1.5.
  • Siloxane functional groups form the backbone of the silicones.
  • silicones consist of an inorganic silicon-oxygen backbone chain ( -Si-O-Si-O-Si-O- ⁇ ⁇ ) with organic side groups attached to the silicon atoms.
  • the side groups are preferably selected from alkyl groups or aryl groups or combinations thereof.
  • organic side groups can be used to link two or more of these -Si-O- backbones together.
  • silicones can be synthesized with a wide variety of properties and compositions.
  • Organic side groups may be alkyl, haloalkyl, aryl, haloaryl, alkoxyl, aralkyl and silacycloalkyl groups as well as more reactive groups such as alkenyl groups such as vinyl, allyl, propenyl, butenyl, pentenyl, hexenyl, heptenyl, octenyl, nonenyl and/or decenyl groups.
  • Polar groups such as acrylate, methacrylate, amino.
  • Imino, hydroxy, epoxy, ester, alkyloxy, isocyanate, phenolic, polyurethane oligomeric, polyamide oligomeric, polyester oligomeric, polyether oligomeric, polyol and carboxypropyl groups may be attached to silicon atoms of the siloxane backbone in any combination.
  • Siloxanes may be terminated with any useful group such as alkenyl and/or alkyl groups such as methyl, ethyl, isopropyl, n-propyl or vinyl groups or combinations thereof.
  • Other groups that may be used to terminate a siloxane are acrylate, methacrylate, amino. Imino, hydroxy, epoxy, ester, alkyloxy, isocyanate, phenolic, poly polyurethane oligomeric, polyamide oligomeric, polyester oligomeric, polyether oligomeric, polyol and carboxypropyl groups and halo, e.g. fluoro groups.
  • Polydialkylsiloxanes (where the organic groups are alkyl groups) are a preferred group of siloxane polymers suitable for use in the composite materials of the present invention.
  • Polydialkylsiloxane polymers may be represented by the following general formula
  • Preferred alkyl groups are linear or branched alkyl groups having 1 to 12, preferably 1 to 8 and more preferably 1 to 4 carbon atoms.
  • polydialkylsiloxanes The best known example of polydialkylsiloxanes is polydimethylsiloxane (where Aik is a methyl group, hereinafter referred to as PDMS), which is also the most preferred polydialkylsiloxane in accordance with the present invention.
  • PDMS polydimethylsiloxane
  • component b) a conductive or semiconductive carbonaceous filler substantially present in the closed porosity volume fraction of the microporous polymer matrix a).
  • Substantially present for the purpose of the present invention means that at least 50, preferably at least 60 and even more preferably at least 70 % of the conductive filler is present in the closed porosity volume fraction. Up to 99, preferably up to 95 and even more preferably up to 90% of the total content of the conductive filler can present in the closed porosity volume fraction of the composite material.
  • carbonaceous filler denotes fillers comprising more than at least 50 wt% of elemental carbon, preferably at last 75 wt% of elemental carbon, more preferably at least 90 wt% of elemental carbon.
  • Especially preferred carbonaceous fillers comprise 99 wt % or more of elemental carbon or consist of elemental carbon.
  • the carbonaceous filler is selected from carbon nanotubes, carbon nanohorns, graphite, graphene and carbon black. Particularly preferred for economical reasons is carbon black.
  • Graphene itself is usually considered as a one-atom thick planar sheet of sp 2 -bonded carbon atoms that are densely packed in a honeycomb structure.
  • the name graphene is derived from graphite and the suffix -ene.
  • Graphite itself consists of a high number of graphene sheets stacked together.
  • Each structure begins with six carbon atoms, tightly bound together chemically in the shape of a regular hexagon - an aromatic structure similar to what is generally referred to as benzene.
  • Carbon nanohorns is the name for horn-shaped sheath aggregate of
  • SWNH Single-walled nanohorns
  • SWNTs single walled nanotubes
  • SWNTs single walled nanotubes
  • SWNHs may associate with each other to form‘dahlia-like' and‘bud-like’ structured aggregates which have an average diameter of about 80-100 nm.
  • the former consists of tubules and graphene sheets protruding from its surface like petals of a dahlia, while the latter is composed of tubules developing inside the particle itself.
  • Carbon black (CAS 1333-86-4)is a form of paracrystalline carbon that has a high surface-area-to-volume ratio, albeit lower than that of activated carbon.
  • carbon black is a colloidal form of elemental carbon consisting of 95 to 99% carbon. It is usually obtained from the partial combustion or thermal decomposition of hydrocarbons, existing as aggregates of aciniform morphology which are composed of spheroidal primary particles, uniformity of primary particle sizes within a given aggregate and
  • Suitable carbonaceous fillers as described above are available from a variety of sources and suppliers and the skilled person will, based on his professional knowledge and the specific application case, select a suitable material for use in the composite material in accordance with the present invention.
  • sperical nanoparticulate fillers with an average diameter of 300 nm or less, preferably of 200 nm or less, have been found to provide certain advantages.
  • average particle diameter of a sperical particle when used herein refers to the D50 median diameter computed on the basis of the intensity weighed particle size distribution as obtained by the so called Contin data inversion algorithm. Generally said, the D50 divides the intensity weighed size distribution into two equal parts, one with sizes smaller than D50 and one with sizes larger than D50.
  • the average particle diameter as defined above is determined according to the following procedure. First, if needed, the particles are isolated from a medium in which they may be contained (as there are various processes for the manufacture of such particles, the products may be available in different forms, e.g. as neat dry particles or as a
  • Measurement temperature is usually at 25 °C and the refractive indices and the viscosity coefficient of the respective dispersion medium used should be known with an accuracy of at least 0.1 %.
  • the cell position should be adjusted for optimal scattered light signal according to the system software.
  • the time averaged intensity scattered by the sample is recorded 5 times.
  • an intensity threshold of 1.10 times the average of the five measurements of the average scattered intensity may be set.
  • the primary laser source attenuator is normally adjusted by the system software and preferably adjusted in the range of about 10,000 cps.
  • a measurement consists of a suitable number of collections of the autocorrelation function (e.g. a set of 200 collections) of a typical duration of a few seconds each and accepted by the system in accordance with the threshold criterion explained above.
  • Data analysis is then carried out on the whole set of recordings of the time autocorrelation function by use of the Contin algorithm available as a software package, which is normally included in the equipment manufacturer's software package.
  • the conducive or semiconductive fillers used in the composite materials accordance with the present invention may deviate form the spherical shape, which is characterized by an aspect ratio of close to 1.
  • Platy particles are also suitable. Typically, platy particles consist
  • acicular particles are also suitable.
  • acicular particles consist essentially of, or even consist of, particles having the shape of, or resembling a needle.
  • fibrous particles are also well known by the skilled in the art.
  • fibrous particles consist essentially of, or even consist of, particles having the shape of, or resembling a fibre, i.e. the particles are slender and greatly elongated, and their length is very high in comparison with the other two dimensions.
  • the fibrous particles which are advantageously contained in the polymer composition in accordance with the instant invention have:
  • - a number average length of typically at least 50 pm, preferably at least 100 pm and more preferably at least 150 pm;
  • - a number average diameter of typically below 25 pm, preferably below 20 pm, and more preferably below 15 pm
  • the average pore diameter determined using image processing of top view SEM images of the composite materials in accordance with the present invention, is preferably in the range from 0.1 to 200 pm. preferably in the range from 0.5 to 100 pm and even more preferably in the range of from 1 to 50 pm. In some cases average pore diameters of from 10 to 30 pm have been found beneficial.
  • SEM is well-suited for quantitative analysis of the pore structure, since it allows a wide range of magnification, a high depth of field, and produces digital data fit for image analysis. SEM combines the best aspects of light microscopy and TEM.
  • the composite material has a specific electric conductivity, in the absence of external pressure, in the range of from 10 -5 to 10 12 S/m, preferably in the range of from 10 6 to 10 9 S/m.
  • Electrical conductivity or specific conductance is the reciprocal of electrical resistivity, and measures a material's ability to conduct an electric current.
  • Relative permittivity is the ratio of the capacitance of a capacitor using that material as a dielectric, compared with a similar capacitor that has vacuum as its dielectric. Relative permittivity is also commonly known as dielectric constant e. Permittivity is a material property that affects the Coulomb force between two point charges in the material. Relative permittivity is the factor by which the electric field between the charges is decreased relative to vacuum.
  • Relative permittivity is a dimensionless number that is in general complex- valued; its real and imaginary parts are denoted as
  • the relative permittivity is an essential piece of information when
  • Capacitance is the ability of a body to store an electric charge.
  • the capacitance of a capacitor is a function only of the geometry of the design (e.g. area of the plates and the distance between them) and the
  • Capacitance can be calculated if the geometry of the conductors and the dielectric properties of the insulator between the conductors are known.
  • the capacitance C is directly propotional to the relative permittivity and inversely proportional to the distance between the plates of the capacitor.
  • the sample preferably in the form of a film, is sandwiched between two metallic disc electrodes and the permittivity is measured in the frequency range from 10 to 10 6 Hz under an applied voltage of 1 V using an impedance analyzer (BioLogic Impedance analyzer MTZ-35).
  • the films comprising such composite materials may span over a wide range without being subject to particular limitations.
  • the upper limit of the permittivity is defined by the composite material becoming conductive i.e. having a conductivity exceeding 10 -4 S/m. Permittivities in the range from 3 to 200, preferably in the range of from 5 to 190 have been achieved.
  • the amount of filler is in the range of from 0.1 to 15, preferably in the range of from 0.5 to 12 wt%, based on the entire weight of the composite.
  • an additional layer of a non-conductive material can be coated on top of the composite material in order to turn the overall material into a non- conductive composite having low conductivity.
  • the porous microstructure of the composite materials in accordance with the present invention allows achieving materials with equivalent elastic moduli that cannot be achieved in a homogeneous material.
  • the porous structure allows significant deformations of the dielectric layer in comparison to a non-porous dielectric layer. This increased deformability leads to large changes of the capacitance under compression.
  • Using an insulating layer coated on the composite material reduces the overall conductivity which allows an increase of the amount of conductive fillers above the percolation threshold within the pores thereby increasing the relative permittivity.
  • Suitable non-conductive materials are e.g. polydialkylsiloxanes, in
  • polydimethyl siloxane PDMS
  • polyesters preferably polyethylene terephthalate polymers.
  • Layers of biaxially oriented polyethylene terephthalate films have been found particularly
  • Mylar ® a product commercially available from DuPont or Hostaphan ® , available from Mitsubishi Chemical Corporation.
  • Another embodiment of the present invention relates to a process for the manufacture of a composite material in accordance with the present invention, comprising the following steps.
  • a second aqueous phase comprising a conductive filler dispersed in water and, optionally, additives to faciliotate and support dispersion of the conductive filler in water
  • step d) subjecting the product obtained in step d) to a heat treatment to remove the water.
  • the composite material in accordance with the process of the present invention is obtained by using an inverse emulsion technology wherein the non-aqueous phase is a mixture of monomer and crosslinker and, optionally, a surfactant, and wherein the aqueous phase is an aqueous solution containing the conductive or semiconductive filler and, optionally, a surfactant.
  • a non-aqueous phase is prepared by using a siloxane polymer precursor, a curing agent and, optionally, a surfactant.
  • the siloxane polymer precursor may be preferably a two component kit as described hereinafter.
  • Two component kits comprising a siloxane precursor polymer and a curing agent are commercially available from a variety of suppliers and the skilled person will select the appropriate precursor products based on his professional knowledge and the needs of the specific application case.
  • Sylgard 184 ® is a silicon elastomer comprising a dimethyl siloxane and an organically modified silica.
  • Sylgard ® 184 is prepared by combining a base (Part A) with a curing agent (Part B).
  • the base includes a siloxane
  • the curing agent also includes a mixture of siloxanes and silica in a solvent including dimethyl methyl hydrogen siloxane, dimethyl-vinyl terminated dimethyl siloxane, dimethylvinlylated and trimethylated silica, tertramethyl tetravinyl cyclitetra siloxane and ethyl benzene.
  • Sylgard ® 527 is a silicone elastomer gel substantially similar to Sylgard
  • silica filler 184 but without the silica filler. It is also prepared from a base and a curing agent.
  • a large variety of siloxane compositions are commercially available from various suppliers.
  • the Sylgard ® series of products is just one example for such suitable two component kits which may be used in the process of the present invention in step a) and which are commercially available e.g. from Dow Chemical.
  • Another group of suitable curable siloxane polymer precursors are the Elastosil ® series of products available from Wacker Chemie.
  • Exemplary PDMS precursors are vinyl-functional PDMS crosslinkable with hydride-functional crosslinking agents or hydroxyl-functional PDMS crosslinkable with hydride functional crosslinking agents or hydroxyl- functional PDMS crosslinkable in the presence of metal catalysts.
  • Sylgard ® 184 is a particularly preferred siloxane polymer precursor which may be used in the process according to the present invention.
  • the siloxane precursor may contain one or more excipients selected from the group of catalysts, inhibitors, flow agents, silicone oils, solvents and fillers.
  • the excipient is selected from the group of catalysts (e.g. Pt complexes for addition curing or Sn complexes for condensation curing) or peroxides (peroxide curing).
  • the non-aqueous phase a) may also optionally comprise a surfactant to stabilize the system.
  • Suitable surfactants for this purpose are known to the skilled person and are available in great variety from a multiplicity of commercial suppliers. The skilled person will, based on his professional expertise select a suitable surfactant.
  • silicone alkyl polyethers such as the Silube®
  • Silicone alykl polyethers are alkylated silicones co-reacted with polyethers. Such surfactants are effective for emulsifying organic oils and silicones with water respectively aquoeus phases.
  • Silube ® products available from Siltech company are represented by the following structure:
  • the surfactant may be added to the siloxane precursor composition and is usually present in an amount from 0.5 to 10 wt%, preferably of from 0.75 to 7.5 wt% of the total weight of non-aqueous phase a).
  • step b) of the process of the present invention an aqueous phase
  • semiconductive filler is preferably added to water, preferably deionized water, under stirrring or under the application of ultrasound to disperse the conductive filler.
  • water preferably deionized water
  • ultrasound to support homogeneous dispersion of the filler the system is preferably cooled e.g. with an ice bath to avoid excessive heating-up of the system.
  • the solution prior to addition of the conductive or semiconductive filler may comprise additives to facilitate and support the dispersion of the
  • a preferred surfactant for this purpose is gum arabic, also known as acacia gum.
  • Acacia gum is a natural gum consisting of the hardened sap of various species of the acacia tree.
  • Gum arabic is a complex mixture of glycoproteins and polysaccharides.
  • step b) the aqueous phase provided in step b) is slowly added to the non-aqueous phase provided in step a) under mechanical stirring in step c) of the process.
  • a high-shear mixer uses a rotating impeller or high-speed rotor, or a series of such impellers or inline rotors, usually powered by an electric motor, to work the fluid, creating flow and shear.
  • the tip velocity, or speed of the fluid at the outside diameter of the rotor will be higher than the velocity at the center of the rotor, and it is this velocity difference that creates shear.
  • a high-shear mixer disperses, or transports, the aqueous phase provided in step b) into the main continuous phase provided in step a) with which it would normally be immiscible, thereby creating an emulsion.
  • the weight ratio of the non-aqueous phase to the aqueous phase is not subject to particular limitations and is usually within the range of 1 :10 to 10:1 , preferably in the range of 1 :5 to 5:1.
  • the non-aqueous phase forms the continuous phase of the system, in which the aqueous phase is dispersed and the amounts of non-. aqueous and aqueos phase are chosen respectively.
  • the weight of the aqueous phase preferably does not exceed the amount of the non-aqueous phase and is usually in the range of form 30 to 40 wt% of th entire emulsion. In some application cases approximately equal weights of non-aqueous and aqueous phase have been found to provide certain advantages.
  • step c) an emulsion is obtained which has droplets of the water
  • the phase containing the conductive filler dispersed in the non-aqueous phase containing the conductive filler dispersed in the non-aqueous phase.
  • the average diameter of these droplets is usually in the range from 0.1 to 300 pm, preferably in the range of from 0.5 to 150 pm and particularly preferred in the range of from 1 to 30 pm.
  • the mean droplet size obtained depends on the viscosity of the continuous phase.
  • Solid materials are then obtained in step d) by reticulating (curing) the emulsion obtained in step c) usually at a temperature below the boiling point of water, preferably in the range from 60 to 95°C for a period of time of 0.5 to 12, preferably from 1 to 8 hours. In some cases, curing times of appr. 4 h have been found to be best.
  • the relative humidity in this step is usually close to 100% or is equivalent to 100%.
  • curing may take place in the form of addition-based curing, such as by the use of Pt as a catalyst wherein Si-H groups of the crosslinking agent react with vinyl groups of the silicone polymer.
  • curing may take place in a
  • condensation based system such as through the use of a Sn based curing system and a room-temperature vulcanizing silicone rubber wherein an alkoxy-crosslinker experiences a hydrolysis step and is left with a hydroxyl group participating in a condensation reaction with another hydroxyl group attached to the polymer in question.
  • curing may take place in a peroxide-based system wherein an organic peroxide compound decomposes at elevated temperatures to form reactive radicals that chemically crosslink the polymer chains.
  • the product obtained in step d) is subjected to a heat treatment to remove the water.
  • the siloxane polymer formed after curing is permeable to water vapor, the droplets leave a porous structure with the conductive or semiconductive filler being sunstantially present in the closed porosity volume fraction of the matrix material, preferably with pore walls being coated with the conductive or semiconductive filler, thereby yielding the composite material in accordance with the present invention.
  • step d) The conditions of curing in step d) and drying in step e) influence the
  • Another embodiment of the present invention relates to a film comprising, preferably consisting essentially of, and even more preferably consisting of the composite material in accordance with the present invention.
  • the thickness of the film is in the range from 1 to 500 pm preferably in the range of from 10 to 250 pm.
  • the films in accordance with the present invention can be obtained by forming the emulsion of step c) of the process in accordance with the present invention into a film by pouring same into a mold before applying step d). The film thus obtained is then subjected to steps d) and e) in accordance with the process of the present invention to obtain the final film suitable for use in pressure sensing devices.
  • the product obtained in step d) is subjected to a heat treatment to remove the water.
  • This heat treatment step is usually carried out at a temperature exceeding the boiling point of water at atmospheric pressure, preferably at a temperature in the range of from 100 to 200°C and for a duration of from 0.1 h to 5 h, preferably of from 0.5 to 5 hours. In some cases temperatures of 130 to 170°C and treatment times of 0.75 to 3 h, particularly of from 1 to 2 h have been found to be suitable.
  • a microporous composite material eventually in film form is obtained, which comprises pores in a closed porosity volume fraction with an average diameter preferably in the range from 0.1 to 200 pm and preferably with the pore walls being lined and the pores being filled with the conductive filler to a certain degree.
  • a further embodiment of the present invention relates to a substrate
  • the substrate is not subject to particular limitations as structure and
  • composition are concerned and the skilled person will select the substrate taking into account the needs of the specific application situation.
  • the structure of the substrate may be adopted to the specific intended use and the substrate may have the function of a carrier for the deformable film or it may provide increased mechanical stability for the said film.
  • the material of the substrate may be metallic or non-metallic respectively insulating or conductive depending on the intended final use of the coated substrate in a pressure sensing device.
  • aluminum substrates or substrates comprising aluminum have been found to provide certain advantages.
  • the coating of the film onto the substrate may be effected using
  • Another embodiment of the present invention relates to multilayer systems comprising a first layer of a film in accordance with the present invention, and, adjacent thereto, a second layer which is an insulating layer.
  • present invention exhibit losses once an amount of conductive filler near to or above the percolation limit is used, which is a certain disadvantage.
  • second layer is an insulating layer.
  • the material of the second insulating layer may be any insulating material which may be formed into a film or a suitable coating on the first layer.
  • insulating layers of thermoplastic polymers are preferred and silicone rubbers or polyesters may be mentioned as examples.
  • the thickness of the second insultaing layer is not subject to particular limitations and often is in the range from 0.5 to 500 pm, preferably in the range from 1 to 100 pm.
  • the insulating layer may be spread onto the films comprising the
  • the insulating layer may itself be deposited on a substrate.
  • material may be achieved by conventional coating techniques such as spin coating, rotation coating or other coating techniques known to the skilled person and described in the literature.
  • the composite materials in accordance with the present invention, the films comprising same and the coated substrates or multilayer structures comprising such films are particularly suitable for use in piezocapacitive devices. Due to their high permittivity at low conductivity, the sensitivity of the devices using said materials is high and very low variations in external pressure can be reliably determined.
  • the composites in accordance with the present invention are excellent candidates for capacitive pressure sensing applications, and more specifically for low force pressure sensors commonly needed for bio-signals such as blood pressure and heart rate monitoring.
  • a solution comprising 5.0 wt% of arabic gum in water was prepared in a flat bottom flask by mixing 5 g of arabic gum (obtained from Sigma Aldrich) with 95 g of deionized water. Magneitc stirring was applied to
  • the carbon black used was purchased from Alfa Aesar under the reference 39724- carbon black and was used as received.
  • the dispersion of the carbon black powder was carried out in a flat-bottom flask by mixing the carbon black powder in the desired amounts and arabic gum solution. The mixture was sonicated for one hour to homogenously disperse the carbon black particles while the solution was cooled in an ice bath to avoid an excessive temperature increase as a result of the sonication. The obtained product was used as the aqueous phase.
  • Sylgard 184 was purchased from Dow Coring as a kit consisting of a PDMS base and a curing agent.
  • the relative dielectric permittivity of the PDMS materials was approximately 2.
  • Silube ® J-208-212 was added as a surfactant to reach a concentration of 5 wt% of surfactant.
  • the aqueous phase was slowly added to the non-aqueous phase under mechanical stirring with a spatula in order to reach a ratio of aqueous phase to non aqueous phase of 50:50.
  • the water-in-oil emulsion thus obtained was poured into a mold having a depth of 500 pm and a diameter of 24 mm and covered. Thereafter the film was reticulated by subjecting the mold to a temperature of 90°C for 4 hours in a water bath (to have 100% humidity). [00146] In the final step, the reticulated film was removed from the mold and placed in an oven at a temperature of 150°C for one hour to remove the water.
  • the composite material obtained had a microporous structure with pores having an average diameter of from 10 to 30 pm.
  • the average pore size was determined on scanning electron microscopy (SEM) images of the products.
  • the carbon black content of the composite material ranged from 4.6 to 10.2 wt%, based on the entire weight of the composite material.
  • the permittivity was determined by broadband dielectric spectroscopy using a sandwich geometry with circular brass electrodes. Measurements were performed at room temperature over frequencies f from 10 Hz to 10 7 Hz. The real part of the permittivity was 3 for a material without any carbon black, 13.5 for a composite material comprising 4.6 wt% of carbon black. At am amount of 10.2 wt% of carbon black the permittivity was determined to be 4000 but the material was conductive as the concentration exceeded percolation threshhold. If the film obtained was formed into a multilayer structure with an insulating film (Mylar film), the permittivity was 330 but the material remained non-conductive.
  • Mylar film insulating film
  • Static sensitivity was measured in compression using circular stainless steel clamps of diameter 25 mm and acting as electrodes.
  • RSA Gil Solids Analyzer was used to maintain a normal pressure on the sample while measuring the complex impedance at 1V and 100Hz using a Keysight Precision LCR Meter.
  • the reference capacitance Co was arbitrarily defined when 0.1 kPa is applied on the sample. Measurement was performed over pressures ranging from 0.1 kPa up to 70 kPa.
  • AC/Co reached values in the range from 0.9 to 1.8 in the pressure range form 2 kPa to 10 kPa. If the carbon black concentration was 10 % and no insulating layer was present, the value for AC/C 0 dropped to values close to 0 at a pressure of 2 kPa. With an insulating layer and a carbon black concentration of 10 wt%, AC/C 0 was approximately 1.8 at a pressure of 2 kPa and exceeded a value of four at a pressure of 10 kPa.

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Abstract

Composite material comprising a) a porous matrix material comprising a siloxane polymer, comprising a closed porosity volume fraction and, optionally, an open porosity volume fraction, and b) a carbonaceous conductive or semiconductive filler substantially present in said closed porosity volume fraction of said porous matrix material a), films, coated substrates and multilayer systems comprising the composite material, and the use thereof in pressure sensing devices.

Description

Structured composites useful as low force sensors
[0001] The present invention relates to composite materials comprising a porous siloxane polymer matrix with a closed porosity volume fraction and a conductive or semiconductive (hereinafter jointly referred to as conductive filler) carbonaceous filler substantially present in said closed porosity volume fraction of the matrix.
[0002] Pressure sensors have attracted much attention in the recent past due to their potential for a variety of different applications. Especially the demand for pressure sensors with high sensitivity in low pressure regions is very high, which systems are needed i.a. for healthcare and medical diagnosis systems as well as in electronic systems, in particular so called e-skin systems.
[0003] Pressure sensing devices are typically categorized into three types,
depending on the parameter being used for the sensing. Piezoresistive devices use the change in conductivity upon application of external pressure. Piezoelectric devices use the piezoelectric effect, i.e. the generation of an electric charge in a material upon application of pressure. The sensitivity of a piezoielectric device is limited by the physical properties of the piezoelectric substance at the origin of the effect.
Piezocapacitive sensors on the other hand make use of the capacitance change occuring in reaction to the aaplication of pressure and their sensitivity is not theoretically limited. The change of capacitance can be a consequence of the distance of two electrodes of the system forming a capacitor changing in reaction to the application of pressure or due to the modification of the equivalent dielectric constant of the dielectric material sandwiched between two electrodes under the application of pressure.
[0004] Compared to piezoresistive devices piezocapacitive sensors offer some advantages such as low power consumption and better reproducability. Compared to piezoelectric devices piezocapacitive sensors are easier to process and easier to shape into different forms. Moreover, they do not require a poling or stretching. [0005] The magnitude of the capacitance change is determined by the change in dielectric constant, the thickness of a dielectric layer and the surface area of an electrode.
[0006] Micro- or nano-structures have been suggested in such devices to improve the sensitivity in particular in the low pressure range. However, this requires usually complex and expensive fabrication processes.
[0007] B.Y. Lee et al, Sensors and Actuators A 240 (2016), 103 to 109 describes low-cost pressure sensors based on dielectric elastomer films with micro- pores. Porous films are prepared by using a siloxane elastomer material and water droplets without any additives. Polydimethylsiloxane is used as a base material and water droplets are selected as dispersion substance.
A solution of PDMS prepolymers , mixed with a curing agent, and water is stirred in a container. Through the stirring process, micro-droplets of water are uniformly dispersed in the PDMS solution due to the insolubility of water. The solution thus obtained is placed between two glass substrates and thereafter the solution is cured. During curing, the water evaporates and a polymerized porous PDMS film having micro-pores where water was initially present is obtained. This film having a thickness of appr. 100 pm forms the dielectric layer of a capacitive type pressure sensor.
[0008] A.J. Gallant, Procedia Chemistry 1 (2009), 568-571 relates to porous
PDMS force sensitive resistors. Elastomeric force sensitive resistors are made from a porous matrix of PDMS filled with carbon black. The PDMS matrix has the form of a sponge and is obtained using a sugar scaffold . Sugar cubes are placed in a dish with PDMS precursors and left for one hour to become saturated with the PDMS. The cubes are then cured, excess PDMS is trimmed away and the cubes are put in a beaker with distilled water to dissolve the sugar. The structure thus obtained is the inverse matrix of the sugar cube in which voids are distributed and oriented in a random configuration. To introduce the carbon black particles a suspension of carbon black in water is added dropwise to the water saturated sponge thereby creating a high concentration of carbon within the open porosity volume fraction of the sponge. Once filled, the sponge is left to dry and a thin layer of PDMS is coated thereon and cured to seal the carbon inside the sponge. In the sponge, the pore walls are lined with carbon. Upon application of pressure, the carbon-black lined pore walls come into contact, thereby increasing the number of carbon-carbon connections and the pores become conducting.
[0009] S.J.A. Majerus,“Flexible, structured MWCNT/PDMS sensors for chronic vascular access monitoring”, IEEE Sensors Book Series: IEEE sensors, published 2016 - Conference 15th IEE Sensors conference Orlando, FL Oct. 30-Nov. 03, 2016, relates to piezoresistive flexible pulsation sensors obtained by applying a so called additive manufacturing method for printing PDMS with an internal porous structure. The pores are reported to have average pore sizes of appr. 1mm. To obtain conductive sensors, multi walled carbon nanotubes are added during the manufacturing process. The resistivity is said to be non-linear and hysteresis was observed. Both are undesired effects.
[0010] It was an object of the present invention to provide composite materials suitable for use in piezocapactive sensors providing high sensitivity and good reproducability.
[0011] This object is achieved with composite materials in accordance with claim 1. Preferred embodiments of the invention are set forth in the dependent claims and in the detailed specification hereinafter.
[0012] A further object of the present invention are films comprising the
composite material in accordance with claim 1 as well as substrates coated with a film made of the composite material in accordance with the present invention.
[0013] The composite material in accordance with the present invention
comprises
a) a porous matrix material comprising a siloxane polymer, comprising a closed porosity volume fraction, and, optionally, an open porosity volume fraction, and
b) a carbonaceous conductive or semiconductive filler substantially present in said closed porosity volume fraction of said porous matrix material a).
[0014] Porous materials are usually characterized by their porosity. Porosity or void fraction is a measure of the void (i.e. "empty") spaces in a material, and is the fraction of the volume of voids over the total volume, between 0 and 1 , or as a percentage between 0% and 100%.
[0015] The apparent porosity or open porosity (oPo) is a fraction of the porosity and is the volume of the open pores, into which a liquid or gas can penetrate, as a percentage of the total volume of the material.
[0016] Non-interconnected voids trapped in the solid phase are not part of the open porosity volume fraction; they are part of the closed porosity volume fraction. This fraction also includes any kind of closed pores in the material.
[0017] Open porosity and closed porosity sum up to the total porosity of the
material.
[0018] The porous matrix material of the composite materials in accordance with the present invention comprises a closed porosity volume fraction, in which a substantial part of the conductive or semiconductive filler is present.
[0019] In accordance with a preferred embodiment of the present invention, the closed porosity volume fraction is preferably equal to or greater than the open porosity volume fraction of the material, i.e. the volume of the pores which form the closed porosity volume fraction is preferably at least equal to or greater than the volume of the pores forming the open porosity volume fraction (the ratio of both pore volume fractions thus preferably is at least 1).
[0020] In accordance with a particularly preferred embodiment, the ratio of the closed porosity volume to the open porosity volume is in the range of from 1 :1 to 100:1 , preferably in the range of from 1.5:1 to 50:1
[0021] The open porosity volume fraction of a porous material can be deternined by gas displacement pycnometry, a technique known to the skilled person. This technique uses the gas displacement method to measure volume accurately. An inert gas, usually He, is used as the displacement gas. A sample of known weight is sealed in a compartment of the measuring device having a known volume. Then He is allowed to flow into the chamber through an inlet valve until equilibrium is reached, i.e. until the pressure is constant. Then the inlet valve is closed and an outlet valve to a second chamber of precisely known volume is opened. The pressures observed upon filling the sample chamber and then upon discharging the gas into the second empty chamber allow the computation of the sample solid phase volume (which equals the volume of gas displaced by the solid part of the sample plus the volume of the pores not accessible to the gas). Helium gas quickly fills even small pores quickly, only the volume part of the sample which cannot be accessed by the He gas displaces the gas. This part of the sample consists of the solid part of the sample plus the volume represented by the closed porosity volume fraction (as same is defined as being not accessible to the gas).
[0022] If the volume displaced by the sample is denoted as Vs, the known volume of the sample cell is denoted as Vc, the volume of the second
compartment into which the gas is displaced is Vr, the pressure after filling the sample cell is Pa and the pressure after expansion into the
compartment cell is Pe, the volume displaced by the sample can be calculated as
[0023] Vs = Vc - Vr (Pe/(Pa-Pe))
[0024] The displaced or pycnometer volume Vs reflects the volume of the solid part of the porous sample (which is referred to herein as as theoretical volume) plus the volume of the closed pores. Theoretical volume can be obtained from the theoretical density of a solid sample without pores, which is usually known for most materials or can be easily determined. Subtracting the theoretical volume from the pycnometer volume yields the volume of the closed pores.
[0025] The bulk volume of the porous sample is the geometric volume of the
porous sample, which is the sum of theoretical volume plus the volume of the closed pores plus the volume of the open pores. Accordingly, the volume of the open pores can be obtained by subtracting the theoretical volume and the closed pore volume (obtained as explained above) from the bulk (geometrical) volume of the sample.
[0026] The open porosity volume fraction is obtained by dividing the volume of the closed pores by the bulk volume. The open porosity volume fraction can be obtained in an analogous manner. The ratio of both fractions is then obtained by simply dividing the closed pore volume fraction by the open porosity volume fraction.
[0027] The total porosity of a porous sample can also be obtained by dividing the bulk density by the theoretical density and subtracting the value from 1.
[0028] The foregoing may be explained through the following example: A sample having a theoretical volume of of 2 cm3 and a pycnometer volume of 3 cm3 has a closed porosity volume fraction of 1 cm3 (obtained by subtracting the theoretical volume from the pycnometer volume). If the porous sample has a geometric (bulk) volume of 4 cm3, the total porosity, based on the bulk volume, is 2/4 or 0.5. The closed porosity volume fraction, relative to the bulk volume, in this case is 0,25, relative to the total pore volume of the sample, 0.5. This yields a ratio closed porosity volume fraction/open porosity volume fraction of 1.
[0029] If, with the same theoretical volume and bulk volume, the pycnometer volume is 3,5 cm3, then the volume of the closed pores is 1 ,5 cm3 which translates into 37,5 % , based on the bulk volume or 75 %, based on the total pore volume. In this case the ratio closed porosity volume fraction to open porosity volume fraction is 3:1.
[0030] The matrix polymer of the composite material in accordance with the
present invention is a siloxane polymer.
[0031] Siloxane polymers or polysiloxanes, also known as silicones, are polymers that include an inert, synthetic compound made up of repeating units of siloxane, frequently combined with carbon or hydrogen or both. They are typically heat-resistant and rubber-like.
[0032] A siloxane is a functional group in organosilicon chemistry with the -Si-O- Si-linkage. The word siloxane is derived from the words silicon, oxygen and alkane. Siloxane materials may be composed of several types of so called siloxide groups, depending on the number of Si-0 bonds: M-units represented by general structural element R3S1O0.5, D-units by the general structural element R2S1O and T-units represented by the general structural element RS1O1.5.
[0033] Siloxane functional groups form the backbone of the silicones.
[0034] More precisely polymerized siloxanes or polysiloxanes, silicones consist of an inorganic silicon-oxygen backbone chain ( -Si-O-Si-O-Si-O-·· ·) with organic side groups attached to the silicon atoms. The side groups are preferably selected from alkyl groups or aryl groups or combinations thereof.
[0035] In some cases, organic side groups can be used to link two or more of these -Si-O- backbones together. By varying the -Si-O- chain lengths, side groups, and crosslinking, silicones can be synthesized with a wide variety of properties and compositions.
[0036] Organic side groups may be alkyl, haloalkyl, aryl, haloaryl, alkoxyl, aralkyl and silacycloalkyl groups as well as more reactive groups such as alkenyl groups such as vinyl, allyl, propenyl, butenyl, pentenyl, hexenyl, heptenyl, octenyl, nonenyl and/or decenyl groups. Polar groups such as acrylate, methacrylate, amino. Imino, hydroxy, epoxy, ester, alkyloxy, isocyanate, phenolic, polyurethane oligomeric, polyamide oligomeric, polyester oligomeric, polyether oligomeric, polyol and carboxypropyl groups may be attached to silicon atoms of the siloxane backbone in any combination.
[0037] Siloxanes may be terminated with any useful group such as alkenyl and/or alkyl groups such as methyl, ethyl, isopropyl, n-propyl or vinyl groups or combinations thereof. Other groups that may be used to terminate a siloxane are acrylate, methacrylate, amino. Imino, hydroxy, epoxy, ester, alkyloxy, isocyanate, phenolic, poly polyurethane oligomeric, polyamide oligomeric, polyester oligomeric, polyether oligomeric, polyol and carboxypropyl groups and halo, e.g. fluoro groups.
[0038] Polydialkylsiloxanes (where the organic groups are alkyl groups) are a preferred group of siloxane polymers suitable for use in the composite materials of the present invention. [0039] Polydialkylsiloxane polymers may be represented by the following general formula
Figure imgf000009_0001
[0040] wherein Aik, which may be the same or different at each occurence,
represents a linear, branched or cyclic alkyl group.
[0041] Preferred alkyl groups are linear or branched alkyl groups having 1 to 12, preferably 1 to 8 and more preferably 1 to 4 carbon atoms.
[0042] The best known example of polydialkylsiloxanes is polydimethylsiloxane (where Aik is a methyl group, hereinafter referred to as PDMS), which is also the most preferred polydialkylsiloxane in accordance with the present invention. The term polydimethylsiloxane or PDMS, when used herein, encompasses derivatives thereof such as hydroxy-, vinyl- allyl- etc. end- capped PDMS.
[0043] The composite materials in accordance with the present invention
comprise as component b) a conductive or semiconductive carbonaceous filler substantially present in the closed porosity volume fraction of the microporous polymer matrix a).
[0044] Substantially present for the purpose of the present invention means that at least 50, preferably at least 60 and even more preferably at least 70 % of the conductive filler is present in the closed porosity volume fraction. Up to 99, preferably up to 95 and even more preferably up to 90% of the total content of the conductive filler can present in the closed porosity volume fraction of the composite material.
[0045] For the purpose of this invention, the term“carbonaceous filler” denotes fillers comprising more than at least 50 wt% of elemental carbon, preferably at last 75 wt% of elemental carbon, more preferably at least 90 wt% of elemental carbon. Especially preferred carbonaceous fillers comprise 99 wt % or more of elemental carbon or consist of elemental carbon.
[0046] Preferably the carbonaceous filler is selected from carbon nanotubes, carbon nanohorns, graphite, graphene and carbon black. Particularly preferred for economical reasons is carbon black.
[0047] Graphene itself is usually considered as a one-atom thick planar sheet of sp2-bonded carbon atoms that are densely packed in a honeycomb structure. The name graphene is derived from graphite and the suffix -ene. Graphite itself consists of a high number of graphene sheets stacked together.
[0048] Graphite, carbon nanotubes, fullerenes and graphene in the sense
referred to above share the same basic structural arrangement of their constituent atoms. Each structure begins with six carbon atoms, tightly bound together chemically in the shape of a regular hexagon - an aromatic structure similar to what is generally referred to as benzene.
[0049] Carbon nanohorns is the name for horn-shaped sheath aggregate of
graphene sheets. Single-walled nanohorns ( SWNH) with about 40-50 nm in tubule length and about 2-3 nm in diameter are derived from single walled nanotubes (SWNTs) and ended by a five-pentagon conical cap with a cone opening angle of ~20. SWNHs may associate with each other to form‘dahlia-like' and‘bud-like’ structured aggregates which have an average diameter of about 80-100 nm. The former consists of tubules and graphene sheets protruding from its surface like petals of a dahlia, while the latter is composed of tubules developing inside the particle itself.
[0050] Carbon black (CAS 1333-86-4)is a form of paracrystalline carbon that has a high surface-area-to-volume ratio, albeit lower than that of activated carbon.
[0051] Chemically, carbon black is a colloidal form of elemental carbon consisting of 95 to 99% carbon. It is usually obtained from the partial combustion or thermal decomposition of hydrocarbons, existing as aggregates of aciniform morphology which are composed of spheroidal primary particles, uniformity of primary particle sizes within a given aggregate and
turbostratic layering within the primary particles.
[0052] Suitable carbonaceous fillers as described above are available from a variety of sources and suppliers and the skilled person will, based on his professional knowledge and the specific application case, select a suitable material for use in the composite material in accordance with the present invention.
[0053] In certain application cases sperical nanoparticulate fillers with an average diameter of 300 nm or less, preferably of 200 nm or less, have been found to provide certain advantages.
[0054] The term average particle diameter of a sperical particle when used herein refers to the D50 median diameter computed on the basis of the intensity weighed particle size distribution as obtained by the so called Contin data inversion algorithm. Generally said, the D50 divides the intensity weighed size distribution into two equal parts, one with sizes smaller than D50 and one with sizes larger than D50.
[0055] In general the average particle diameter as defined above is determined according to the following procedure. First, if needed, the particles are isolated from a medium in which they may be contained (as there are various processes for the manufacture of such particles, the products may be available in different forms, e.g. as neat dry particles or as a
suspension in a suitable dispersion medium. The neat particles are then used for the determination of the particle size distribution preferably by the method of dynamic light scattering. In this regard the method as described in ISO Norm Particles size analysis - Dynamic Light Scattering (DLS), ISO 22412:2008(E) is recommended to be followed. This norm provides i.a. for instructions relating to instrument location (section 8.1.), system
qualification (section 10), sample requirements (section 8.2.),
measurement procedure (section 9 points 1 to 5 and 7) and repeatability (section 11). Measurement temperature is usually at 25 °C and the refractive indices and the viscosity coefficient of the respective dispersion medium used should be known with an accuracy of at least 0.1 %. After appropriate temperature equilibration the cell position should be adjusted for optimal scattered light signal according to the system software. Before starting the collection of the time autocorrelation function the time averaged intensity scattered by the sample is recorded 5 times. In order to eliminate possible signals of dust particles moving fortuitously through the measuring volume an intensity threshold of 1.10 times the average of the five measurements of the average scattered intensity may be set. The primary laser source attenuator is normally adjusted by the system software and preferably adjusted in the range of about 10,000 cps.
Subsequent measurements of the time autocorrelation functions during which the average intensity threshold set as above is exceeded should be disregarded.
[0056] Usually a measurement consists of a suitable number of collections of the autocorrelation function (e.g. a set of 200 collections) of a typical duration of a few seconds each and accepted by the system in accordance with the threshold criterion explained above. Data analysis is then carried out on the whole set of recordings of the time autocorrelation function by use of the Contin algorithm available as a software package, which is normally included in the equipment manufacturer's software package.
[0057] The conducive or semiconductive fillers used in the composite materials accordance with the present invention may deviate form the spherical shape, which is characterized by an aspect ratio of close to 1.
[0058] Platy particles are also suitable. Typically, platy particles consist
essentially of, or even consist of, particles having the shape of, or resembling to a plate, i.e. the particles are flat or nearly flat and their thickness is small in comparison with the other two dimensions.
[0059] Acicular particles are also suitable. Typically, acicular particles consist essentially of, or even consist of, particles having the shape of, or resembling a needle.
[0060] Finally, fibrous particles are also well known by the skilled in the art.
Typically, fibrous particles consist essentially of, or even consist of, particles having the shape of, or resembling a fibre, i.e. the particles are slender and greatly elongated, and their length is very high in comparison with the other two dimensions. Notably to the purpose of increased reinforcement, the fibrous particles which are advantageously contained in the polymer composition in accordance with the instant invention, have:
- a number average aspect ratio of typically above 5, preferably above 10 and more preferably above 15;
- a number average length of typically at least 50 pm, preferably at least 100 pm and more preferably at least 150 pm; and
- a number average diameter of typically below 25 pm, preferably below 20 pm, and more preferably below 15 pm
[0061] The average pore diameter, determined using image processing of top view SEM images of the composite materials in accordance with the present invention, is preferably in the range from 0.1 to 200 pm. preferably in the range from 0.5 to 100 pm and even more preferably in the range of from 1 to 50 pm. In some cases average pore diameters of from 10 to 30 pm have been found beneficial.
[0062] SEM is well-suited for quantitative analysis of the pore structure, since it allows a wide range of magnification, a high depth of field, and produces digital data fit for image analysis. SEM combines the best aspects of light microscopy and TEM.
[0063] A typical procedure for determining average pore diameter is desribed in more detail as follows:
[0064] A gray scale analysis of the pictures using the software package ImageJ was performed to determine the pore size distribution by thresholding the pictures in order to select the internal area of the pores and then using the Particle Analysis package. This procedure allows the identification of the pore area distribution. Assuming that pores have a spherical shape and are cut through their centers therefore exhibiting their equivalent great circle, the pore size D was extracted as the equivalent diameter from the surface area A, ie D=2 sqrt(A/pi). The average and the standard deviation of pore size were obtained via a statistical analysis accumulating pore size distribution over several pictures (e.g., 10 pictures for a given sample). [0065] In accordance with another preferred embodiment of the present invention, the composite material has a specific electric conductivity, in the absence of external pressure, in the range of from 10-5 to 10 12 S/m, preferably in the range of from 106 to 109 S/m.
[0066] Electrical conductivity or specific conductance is the reciprocal of electrical resistivity, and measures a material's ability to conduct an electric current.
[0067] For capacitive devices, i.e. devices using a change in capacitance upon application of external pressure, it is desirable to obtain a high dielectric function of the material without the material becoming conductive.
[0068] It is desirable to obtain a large variation of the relative capacitance change AC/Co (Co represents the capacitance without application of external pressure whereas AC represents the change in capacitance upon application of a given pressure) under mechanical compression in order to be considered as good piezocapactive sensor. Increasing the amount of conductive filler increases the variation of AC/C0.
[0069] Relative permittivity is the ratio of the capacitance of a capacitor using that material as a dielectric, compared with a similar capacitor that has vacuum as its dielectric. Relative permittivity is also commonly known as dielectric constant e. Permittivity is a material property that affects the Coulomb force between two point charges in the material. Relative permittivity is the factor by which the electric field between the charges is decreased relative to vacuum.
[0070] Relative permittivity is a dimensionless number that is in general complex- valued; its real and imaginary parts are denoted as
[0071] e = e’ - i e”
[0072] where e’ is the real part of the permittivity and e” the imaginary part of the permittivity.
[0073] The relative permittivity is an essential piece of information when
designing capacitors, and in other circumstances where a material might be expected to introduce capacitance into a circuit. If a material with a high relative permittivity is placed in an electric field, the magnitude of that field will be measurably reduced within the volume of the dielectric. [0074] Capacitance is the ability of a body to store an electric charge. The capacitance of a capacitor is a function only of the geometry of the design (e.g. area of the plates and the distance between them) and the
permittivity of the dielectric material between the plates of the capacitor.
[0075] Capacitance can be calculated if the geometry of the conductors and the dielectric properties of the insulator between the conductors are known. The capacitance C is directly propotional to the relative permittivity and inversely proportional to the distance between the plates of the capacitor.
[0076] Upon application of an external pressure, the distance of the pore walls of a pore within the composite material (which constitute the plates of a deemed capacitor) is reduced, thereby increasing the capacitance of the capacitor. This yields the value for AC at a given pressure. The higher the relative permittivity of the material between the plates of the capacitor, the higher AC becomes. Thus, achieving a relative permittivity as high as possible is desired.
[0077] The relative permittivity in accordance with the present invention is
measured as follows: The sample, preferably in the form of a film, is sandwiched between two metallic disc electrodes and the permittivity is measured in the frequency range from 10 to 106 Hz under an applied voltage of 1 V using an impedance analyzer (BioLogic Impedance analyzer MTZ-35).
[0078] The permittivity (dielectric constant) of the composite materials in
accordance with the present invention (as well as of the films comprising such composite materials) may span over a wide range without being subject to particular limitations. The higher the permittivity, the higher the sensibility for pressure sensing applications. The upper limit of the permittivity is defined by the composite material becoming conductive i.e. having a conductivity exceeding 10-4 S/m. Permittivities in the range from 3 to 200, preferably in the range of from 5 to 190 have been achieved.
[0079] It is not desirable, however, that the material becomes conductive.
[0080] Increasing the amount of conductive filler within the pores increases the relative permittivity but once the percolation point is reached, the material becomes conductive which is undesired. Localizing the conductive filler within the closed porosity volume fraction increases the amount of filler needed to reach the percolation point thereby retaining a low conductivity while significantly increasing relative permittivity, which improves the signal when external pressure is applied and the distance between the pore walls (forming the plates of the capacitor) is reduced.
[0081] Overall, this leads to a very good sensitivity of the capacitance sensors made using the composite material of the present invention.
[0082] In accordance with a preferred embodiment of the present invention, the amount of filler is in the range of from 0.1 to 15, preferably in the range of from 0.5 to 12 wt%, based on the entire weight of the composite.
[0083] For an amount of conductive filler close or above the percolation point, an additional layer of a non-conductive material can be coated on top of the composite material in order to turn the overall material into a non- conductive composite having low conductivity.
[0084] The porous microstructure of the composite materials in accordance with the present invention allows achieving materials with equivalent elastic moduli that cannot be achieved in a homogeneous material. The porous structure allows significant deformations of the dielectric layer in comparison to a non-porous dielectric layer. This increased deformability leads to large changes of the capacitance under compression.
[0085] Using an insulating layer coated on the composite material reduces the overall conductivity which allows an increase of the amount of conductive fillers above the percolation threshold within the pores thereby increasing the relative permittivity.
[0086] Suitable non-conductive materials are e.g. polydialkylsiloxanes, in
particular polydimethyl siloxane (PDMS) and polyesters, preferably polyethylene terephthalate polymers. Layers of biaxially oriented polyethylene terephthalate films have been found particularly
advantageous in certain application cases. Just by way of example for such films, there may be mentioned Mylar®, a product commercially available from DuPont or Hostaphan®, available from Mitsubishi Chemical Corporation.
[0087] Another embodiment of the present invention relates to a process for the manufacture of a composite material in accordance with the present invention, comprising the following steps.
[0088] a) providing a first non-aqueous phase comprising a siloxane polymer precursor and a curing agent and, optionally, a surfactant,
b) providing a second aqueous phase comprising a conductive filler dispersed in water and, optionally, additives to faciliotate and support dispersion of the conductive filler in water,
c) preparing an emulsion by adding aqueous phase b) to the non-aqueous phase a) under stirring,
d) reticulating the product obtained in step c) and , finally,
e) subjecting the product obtained in step d) to a heat treatment to remove the water.
[0089] The composite material in accordance with the process of the present invention is obtained by using an inverse emulsion technology wherein the non-aqueous phase is a mixture of monomer and crosslinker and, optionally, a surfactant, and wherein the aqueous phase is an aqueous solution containing the conductive or semiconductive filler and, optionally, a surfactant.
[0090] In step a) of the process of the present invention, a non-aqueous phase is prepared by using a siloxane polymer precursor, a curing agent and, optionally, a surfactant.
[0091] The siloxane polymer precursor may be preferably a two component kit as described hereinafter.
[0092] Two component kits comprising a siloxane precursor polymer and a curing agent are commercially available from a variety of suppliers and the skilled person will select the appropriate precursor products based on his professional knowledge and the needs of the specific application case.
[0093] Just by way of example, the principal constitution of such two component kit is explained in more detail for Sylgard®184. [0094] Sylgard 184® is a silicon elastomer comprising a dimethyl siloxane and an organically modified silica. Sylgard® 184 is prepared by combining a base (Part A) with a curing agent (Part B). The base includes a siloxane
(dimethyl-vinyl terminated dimethyl siloxane) and a dimethylvinylated and trimethylated silica) in a solvent (ethyl benzene). The curing agent also includes a mixture of siloxanes and silica in a solvent including dimethyl methyl hydrogen siloxane, dimethyl-vinyl terminated dimethyl siloxane, dimethylvinlylated and trimethylated silica, tertramethyl tetravinyl cyclitetra siloxane and ethyl benzene.
[0095] Sylgard® 527 is a silicone elastomer gel substantially similar to Sylgard
184 but without the silica filler. It is also prepared from a base and a curing agent. A large variety of siloxane compositions are commercially available from various suppliers. The Sylgard® series of products is just one example for such suitable two component kits which may be used in the process of the present invention in step a) and which are commercially available e.g. from Dow Chemical. Another group of suitable curable siloxane polymer precursors are the Elastosil® series of products available from Wacker Chemie.
[0096] Exemplary PDMS precursors are vinyl-functional PDMS crosslinkable with hydride-functional crosslinking agents or hydroxyl-functional PDMS crosslinkable with hydride functional crosslinking agents or hydroxyl- functional PDMS crosslinkable in the presence of metal catalysts.
[0097] Sylgard® 184 is a particularly preferred siloxane polymer precursor which may be used in the process according to the present invention.
[0098] The siloxane precursor may contain one or more excipients selected from the group of catalysts, inhibitors, flow agents, silicone oils, solvents and fillers. In one embodiment the excipient is selected from the group of catalysts (e.g. Pt complexes for addition curing or Sn complexes for condensation curing) or peroxides (peroxide curing).
[0099] The non-aqueous phase a) may also optionally comprise a surfactant to stabilize the system. Suitable surfactants for this purpose are known to the skilled person and are available in great variety from a multiplicity of commercial suppliers. The skilled person will, based on his professional expertise select a suitable surfactant.
[00100] Just by way of example, silicone alkyl polyethers such as the Silube®
series of products may be mentioned here as suitable surfactants. Silicone alykl polyethers are alkylated silicones co-reacted with polyethers. Such surfactants are effective for emulsifying organic oils and silicones with water respectively aquoeus phases.
[00101] The Silube® products available from Siltech company are represented by the following structure:
Figure imgf000019_0001
[00102]
[00103] The surfactant may be added to the siloxane precursor composition and is usually present in an amount from 0.5 to 10 wt%, preferably of from 0.75 to 7.5 wt% of the total weight of non-aqueous phase a).
[00104] In step b) of the process of the present invention, an aqueous phase
comprising the conductive or semiconductive filler dispersed therein, is provided.
[00105] To obtain the aqueous phase provided in step b), the conductive or
semiconductive filler is preferably added to water, preferably deionized water, under stirrring or under the application of ultrasound to disperse the conductive filler. When using ultrasound to support homogeneous dispersion of the filler the system is preferably cooled e.g. with an ice bath to avoid excessive heating-up of the system.
[00106] The solution prior to addition of the conductive or semiconductive filler may comprise additives to facilitate and support the dispersion of the
conductive or semiconductive filler. A preferred surfactant for this purpose, is gum arabic, also known as acacia gum. Acacia gum is a natural gum consisting of the hardened sap of various species of the acacia tree. Gum arabic is a complex mixture of glycoproteins and polysaccharides. [00107] The skilled person is aware of further additives which facilitate and support the dispersion of conductive and semiconductive fillers in aqueous systems and respective products are commercially available in great variety from a number of different suppliers so that no further details have to be given here. The skilled person will select a suitable dispersion aid based on his professional knowledge and experience.
[00108] To obtain the emulsion, the aqueous phase provided in step b) is slowly added to the non-aqueous phase provided in step a) under mechanical stirring in step c) of the process.
[00109] Fluid undergoes shear when one area of fluid travels with a different
velocity relative to an adjacent area. A high-shear mixer uses a rotating impeller or high-speed rotor, or a series of such impellers or inline rotors, usually powered by an electric motor, to work the fluid, creating flow and shear. The tip velocity, or speed of the fluid at the outside diameter of the rotor, will be higher than the velocity at the center of the rotor, and it is this velocity difference that creates shear.
[00110] In a preferred embodiment, a high-shear mixer disperses, or transports, the aqueous phase provided in step b) into the main continuous phase provided in step a) with which it would normally be immiscible, thereby creating an emulsion.
[00111] The skilled person will select the diameter of the stirrer and its rotational speed (and thereby defining the shear rate applied) in accordance with the needs of the specific application situation and the desired final morphology of the product.
[00112] Through the application of high shear rates it has been surprisingly found that it is possible to uniformly distribute high amounts of the non-aqueous phase in the silicone rubber and to form a stable emulsion, said emulsion being stable over extended periods of time.
[00113] The weight ratio of the non-aqueous phase to the aqueous phase is not subject to particular limitations and is usually within the range of 1 :10 to 10:1 , preferably in the range of 1 :5 to 5:1. Preferably, the non-aqueous phase forms the continuous phase of the system, in which the aqueous phase is dispersed and the amounts of non-. aqueous and aqueos phase are chosen respectively. In such case, the weight of the aqueous phase preferably does not exceed the amount of the non-aqueous phase and is usually in the range of form 30 to 40 wt% of th entire emulsion. In some application cases approximately equal weights of non-aqueous and aqueous phase have been found to provide certain advantages.
[00114] After step c) an emulsion is obtained which has droplets of the water
phase containing the conductive filler dispersed in the non-aqueous phase. The average diameter of these droplets is usually in the range from 0.1 to 300 pm, preferably in the range of from 0.5 to 150 pm and particularly preferred in the range of from 1 to 30 pm. The mean droplet size obtained depends on the viscosity of the continuous phase.
[00115] Solid materials are then obtained in step d) by reticulating (curing) the emulsion obtained in step c) usually at a temperature below the boiling point of water, preferably in the range from 60 to 95°C for a period of time of 0.5 to 12, preferably from 1 to 8 hours. In some cases, curing times of appr. 4 h have been found to be best. The relative humidity in this step is usually close to 100% or is equivalent to 100%.
[00116] In one embodiment, curing may take place in the form of addition-based curing, such as by the use of Pt as a catalyst wherein Si-H groups of the crosslinking agent react with vinyl groups of the silicone polymer.
[00117] In accordance with another embodiment, curing may take place in a
condensation based system, such as through the use of a Sn based curing system and a room-temperature vulcanizing silicone rubber wherein an alkoxy-crosslinker experiences a hydrolysis step and is left with a hydroxyl group participating in a condensation reaction with another hydroxyl group attached to the polymer in question.
[00118] In still another embodiment, curing may take place in a peroxide-based system wherein an organic peroxide compound decomposes at elevated temperatures to form reactive radicals that chemically crosslink the polymer chains. [00119] In the final step, the product obtained in step d) is subjected to a heat treatment to remove the water. As the siloxane polymer formed after curing is permeable to water vapor, the droplets leave a porous structure with the conductive or semiconductive filler being sunstantially present in the closed porosity volume fraction of the matrix material, preferably with pore walls being coated with the conductive or semiconductive filler, thereby yielding the composite material in accordance with the present invention.
[00120] The conditions of curing in step d) and drying in step e) influence the
morphology of the porous composite material and the skilled person will select the conditions thereof in a suitable manner to obtain the desired morphology.
[00121] Another embodiment of the present invention relates to a film comprising, preferably consisting essentially of, and even more preferably consisting of the composite material in accordance with the present invention.
[00122] In accordance with a preferred embodiment, the thickness of the film is in the range from 1 to 500 pm preferably in the range of from 10 to 250 pm.
[00123] The films in accordance with the present invention can be obtained by forming the emulsion of step c) of the process in accordance with the present invention into a film by pouring same into a mold before applying step d). The film thus obtained is then subjected to steps d) and e) in accordance with the process of the present invention to obtain the final film suitable for use in pressure sensing devices.
[00124] In the final step of the process in accordance with the present invention, the product obtained in step d) is subjected to a heat treatment to remove the water. This heat treatment step is usually carried out at a temperature exceeding the boiling point of water at atmospheric pressure, preferably at a temperature in the range of from 100 to 200°C and for a duration of from 0.1 h to 5 h, preferably of from 0.5 to 5 hours. In some cases temperatures of 130 to 170°C and treatment times of 0.75 to 3 h, particularly of from 1 to 2 h have been found to be suitable. [00125] After the final step, a microporous composite material, eventually in film form is obtained, which comprises pores in a closed porosity volume fraction with an average diameter preferably in the range from 0.1 to 200 pm and preferably with the pore walls being lined and the pores being filled with the conductive filler to a certain degree.
[00126] A further embodiment of the present invention relates to a substrate
coated with a film according to the present invention.
[00127] The substrate is not subject to particular limitations as structure and
composition are concerned and the skilled person will select the substrate taking into account the needs of the specific application situation.
[00128] The structure of the substrate may be adopted to the specific intended use and the substrate may have the function of a carrier for the deformable film or it may provide increased mechanical stability for the said film.
[00129] The material of the substrate may be metallic or non-metallic respectively insulating or conductive depending on the intended final use of the coated substrate in a pressure sensing device. In some cases, aluminum substrates or substrates comprising aluminum have been found to provide certain advantages.
[00130] The coating of the film onto the substrate may be effected using
conventional coating techniques known to the skilled person which have been described in the literature so that no further details need to be given here.
[00131] Another embodiment of the present invention relates to multilayer systems comprising a first layer of a film in accordance with the present invention, and, adjacent thereto, a second layer which is an insulating layer.
[00132] The films comprising the composite material in accordance with the
present invention exhibit losses once an amount of conductive filler near to or above the percolation limit is used, which is a certain disadvantage.
[00133] The multilayer systems in accordance with the present invention overcome these disadvantages by adding a second layer onto the films in
accordance with the present invention which second layer is an insulating layer. Thereby, the high permittivity of the material is maintained while at the same time the conductivity is significantly reduced.
[00134] The material of the second insulating layer may be any insulating material which may be formed into a film or a suitable coating on the first layer. For economical and processability reasons, insulating layers of thermoplastic polymers are preferred and silicone rubbers or polyesters may be mentioned as examples. Mylar®films based on polyethylene terephthalate polymers, which are commercially available from a number of suppliers, have been found advantageous in terms of processabity and costs and thus represent a particularly preferred group of insulating materials for the second insulation layer.
[00135] The thickness of the second insultaing layer is not subject to particular limitations and often is in the range from 0.5 to 500 pm, preferably in the range from 1 to 100 pm.
[00136] The insulating layer may be spread onto the films comprising the
composite material in accordance with the present invention. The insulating layer may itself be deposited on a substrate.
[00137] Coating of the insulating layer onto the film comprising the composite
material may be achieved by conventional coating techniques such as spin coating, rotation coating or other coating techniques known to the skilled person and described in the literature.
[00138] The composite materials in accordance with the present invention, the films comprising same and the coated substrates or multilayer structures comprising such films are particularly suitable for use in piezocapacitive devices. Due to their high permittivity at low conductivity, the sensitivity of the devices using said materials is high and very low variations in external pressure can be reliably determined.
[00139] When a compressive stress is applied on the microporous composite
material in accordance with the present invention, a large deformation is created as well as a modification of its microstructure. Both effects lead to large variation of the equivalent capacitance and therefore to a large piezocapacitive sensitivity at low external pressures e.g.in the range of from 0.1 kPa to 10kPa. Accordingly, the composites in accordance with the present invention are excellent candidates for capacitive pressure sensing applications, and more specifically for low force pressure sensors commonly needed for bio-signals such as blood pressure and heart rate monitoring.
[00140] Example 1
[00141] A solution comprising 5.0 wt% of arabic gum in water was prepared in a flat bottom flask by mixing 5 g of arabic gum (obtained from Sigma Aldrich) with 95 g of deionized water. Magneitc stirring was applied to
homogeneously dissolve the arabic gum which serves as a surfactant to disperse carbon black poweder (the conductive filler). The carbon black used was purchased from Alfa Aesar under the reference 39724- carbon black and was used as received.
[00142] The dispersion of the carbon black powder was carried out in a flat-bottom flask by mixing the carbon black powder in the desired amounts and arabic gum solution. The mixture was sonicated for one hour to homogenously disperse the carbon black particles while the solution was cooled in an ice bath to avoid an excessive temperature increase as a result of the sonication. The obtained product was used as the aqueous phase.
[00143] As non-aqueous phase, Sylgard 184 was purchased from Dow Coring as a kit consisting of a PDMS base and a curing agent. The relative dielectric permittivity of the PDMS materials was approximately 2. To the mixture of PDMS base and crosslinker, Silube® J-208-212 was added as a surfactant to reach a concentration of 5 wt% of surfactant.
[00144] The aqueous phase was slowly added to the non-aqueous phase under mechanical stirring with a spatula in order to reach a ratio of aqueous phase to non aqueous phase of 50:50.
[00145] The water-in-oil emulsion thus obtained was poured into a mold having a depth of 500 pm and a diameter of 24 mm and covered. Thereafter the film was reticulated by subjecting the mold to a temperature of 90°C for 4 hours in a water bath (to have 100% humidity). [00146] In the final step, the reticulated film was removed from the mold and placed in an oven at a temperature of 150°C for one hour to remove the water.
[00147] The composite material obtained had a microporous structure with pores having an average diameter of from 10 to 30 pm. The average pore size was determined on scanning electron microscopy (SEM) images of the products.
[00148] The carbon black content of the composite material ranged from 4.6 to 10.2 wt%, based on the entire weight of the composite material.
[00149] The permittivity was determined by broadband dielectric spectroscopy using a sandwich geometry with circular brass electrodes. Measurements were performed at room temperature over frequencies f from 10 Hz to 107 Hz. The real part of the permittivity was 3 for a material without any carbon black, 13.5 for a composite material comprising 4.6 wt% of carbon black. At am amount of 10.2 wt% of carbon black the permittivity was determined to be 4000 but the material was conductive as the concentration exceeded percolation threshhold. If the film obtained was formed into a multilayer structure with an insulating film (Mylar film), the permittivity was 330 but the material remained non-conductive.
[00150] Static sensitivity was measured in compression using circular stainless steel clamps of diameter 25 mm and acting as electrodes. RSA Gil Solids Analyzer was used to maintain a normal pressure on the sample while measuring the complex impedance at 1V and 100Hz using a Keysight Precision LCR Meter. In order to estimate the equivalent capacitance Cp and resistance Rp of the sample it was assumed that the material acts as the combination of a resistor and a capacitor in parallel. The reference capacitance Co was arbitrarily defined when 0.1 kPa is applied on the sample. Measurement was performed over pressures ranging from 0.1 kPa up to 70 kPa.
[00151] For carbon black concentrations of 4.2 wt% without an insulating layer, AC/Co reached values in the range from 0.9 to 1.8 in the pressure range form 2 kPa to 10 kPa. If the carbon black concentration was 10 % and no insulating layer was present, the value for AC/C0 dropped to values close to 0 at a pressure of 2 kPa. With an insulating layer and a carbon black concentration of 10 wt%, AC/C0 was approximately 1.8 at a pressure of 2 kPa and exceeded a value of four at a pressure of 10 kPa.
[00152] These results show the excellent sensitivity of the composite materials in accordance with the present invention for use in piezocapacitive sensing devices.

Claims

Claims
1. Composite material comprising
a) a porous matrix material comprising a siloxane polymer, comprising a closed porosity volume fraction, and, optionally, an open porosity volume fraction, and
b) a carbonaceous conductive or semiconductive filler substantially present in said closed porosity volume fraction of said porous matrix material a).
2. The composite material in accordance with claim 1 wherein the ratio of closed porosity volume fraction to open porosity volume fraction is at least 1 :1 , preferably 1 :1 to 100:1.
3. The composite material of claim 1or 2 having an electrical conductivity, in the absence of external pressure, in the range of from 105 to 10 12 S/m.
4. The composite material of any of claims claim 1 to 3 wherein the amount of filler is in the range of from 0.1 to 15 wt %, based on the entire weight of the composite.
5. The composite material of any of claims 1 to 4 wherein the siloxane polymer polymer is a polydimethylsiloxane (PDMS).
6. The composite material of any of claims 1 to 5 wherein the conductive or
semiconductive filler is selected from carbon nanotubes, carbon nanohorns, graphite, graphene and carbon black.
7. The composite material of claim 6 wherein the conductive or semiconductive filler is carbon black.
8. Film comprising the composite material of any of claims 1 to 7.
9. The film of claim 8 having a thickness in the range of from 1 to 500 pm.
10. Substrate coated with a film in accordance with any of claims 8 or 9.
11. Multilayer system comprising a first layer of a film in accordance with any of claims 8 or 9 and, adjacent thereto, a second layer which is an insulating layer.
12. Multilayer system in accordance with claim 11 wherein the second layer is a polyester layer, particularly a polyethylene terephthalate layer.
13. A process for the manufacture of a composite material in accordance with any of claims 1 to 8 comprising the following steps:
a) providing a first non-aqueous phase comprising a siloxane polymer
1 precursor and a curing agent and, optionally, a surfactant,
b) providing a second aqueous phase comprising a conductive nor
semiconductive filler dispersed in water,
c) preparing an emulsion by adding aqueous phase b) to the non-aqueous phase a) under stirring,
d) reticulating the product obtained in step c) and , finally,
d) subjecting the product obtained in step d) to a heat treatment to remove the water.
14. The process of claim 12 for manufacturing a film in accordance with claim 8 or 9 wherein the emulsion obtained in step c) is formed into a film by pouring same into a mold before applying step d).
15. Use of the composite material in accordance with any of claims 1 to 7 or of the film in accordance with claim 8 or 9 or of the substrate in accordance with claim 10 or of the multilayer structure in accordance with claim 11 or 12 for use in pressure sensing devices.
2
PCT/EP2018/050002 2018-01-01 2018-01-01 Structured composites useful as low force sensors WO2019129387A1 (en)

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PCT/EP2018/050002 WO2019129387A1 (en) 2018-01-01 2018-01-01 Structured composites useful as low force sensors
JP2020536619A JP7026238B2 (en) 2018-01-01 2018-04-18 Devices including pressure sensitive layers and pressure sensitive layers
CN201880090630.9A CN112004874B (en) 2018-01-01 2018-04-18 Pressure sensing layer and device including the same
PCT/EP2018/059956 WO2019129390A1 (en) 2018-01-01 2018-04-18 Pressure sensing layers and devices comprising same
EP18716646.7A EP3735438A1 (en) 2018-01-01 2018-04-18 Pressure sensing layers and devices comprising same
PCT/EP2018/059957 WO2019129391A1 (en) 2018-01-01 2018-04-18 Pressure sensing layers and devices comprising same
KR1020207022277A KR102560957B1 (en) 2018-01-01 2018-04-18 Pressure Sensing Layer and Device Including the Same
BR112020013390-6A BR112020013390A2 (en) 2018-01-01 2018-04-18 pressure perception layer, device and monitor, substrate, composite material, film, multilayer system, use, and, process for making a composite material.
US16/958,882 US20200337569A1 (en) 2018-01-01 2018-04-18 Pressure sensing layers and devices comprising same

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Cited By (4)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
CN113845673A (en) * 2021-05-31 2021-12-28 复旦大学 Preparation method of step curing silica gel film and application of step curing silica gel film in field of epidermal electronics
CN114262520A (en) * 2022-01-20 2022-04-01 青岛科技大学 Preparation method of flexible stretchable silicone rubber-based strain sensor based on emulsion blending
CN114381032A (en) * 2022-01-20 2022-04-22 苏州大学 Three-phase PDMS composite material preparation method based on seepage theory and intelligent foot pad
CN116178780A (en) * 2022-12-28 2023-05-30 苏州微光电子融合技术研究院有限公司 Preparation method of carbon material doped polydimethylsiloxane flexible porous strain sensor

Citations (2)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
CN106633891A (en) * 2016-10-21 2017-05-10 四川大学 Silicon rubber based porous dielectric elastomer composite material and preparation method thereof
KR101753247B1 (en) * 2016-06-30 2017-07-04 엘지이노텍 주식회사 Pressure sensing sensor and pressure sensing apparatus comprising the same

Patent Citations (2)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
KR101753247B1 (en) * 2016-06-30 2017-07-04 엘지이노텍 주식회사 Pressure sensing sensor and pressure sensing apparatus comprising the same
CN106633891A (en) * 2016-10-21 2017-05-10 四川大学 Silicon rubber based porous dielectric elastomer composite material and preparation method thereof

Non-Patent Citations (5)

* Cited by examiner, † Cited by third party
Title
A.J. GALLANT, PROCEDIA CHEMISTRY, vol. 1, 2009, pages 568 - 571
B.Y. LEE ET AL., SENSORS AND ACTUATORS A, vol. 240, 2016, pages 103 - 109
DATABASE WPI Week 201747, Derwent World Patents Index; AN 2017-32224M, XP002781910 *
DATABASE WPI Week 201752, Derwent World Patents Index; AN 2017-517173, XP002781921 *
S.J.A. MAJERUS: "Flexible, structured MWCNT/PDMS sensors for chronic vascular access monitoring", IEEE SENSORS BOOK SERIES: IEEE SENSORS, PUBLISHED 2016 - CONFERENCE 15TH IEE SENSORS CONFERENCE ORLANDO, 30 October 2016 (2016-10-30)

Cited By (6)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
CN113845673A (en) * 2021-05-31 2021-12-28 复旦大学 Preparation method of step curing silica gel film and application of step curing silica gel film in field of epidermal electronics
CN113845673B (en) * 2021-05-31 2023-08-01 复旦大学 Preparation method of step-cured silica gel film and application of step-cured silica gel film in field of skin electronics
CN114262520A (en) * 2022-01-20 2022-04-01 青岛科技大学 Preparation method of flexible stretchable silicone rubber-based strain sensor based on emulsion blending
CN114381032A (en) * 2022-01-20 2022-04-22 苏州大学 Three-phase PDMS composite material preparation method based on seepage theory and intelligent foot pad
CN114262520B (en) * 2022-01-20 2022-12-02 青岛科技大学 Preparation method of flexible stretchable silicone rubber-based strain sensor based on emulsion blending
CN116178780A (en) * 2022-12-28 2023-05-30 苏州微光电子融合技术研究院有限公司 Preparation method of carbon material doped polydimethylsiloxane flexible porous strain sensor

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