Classifications

• • H—ELECTRICITY
  • H10—SEMICONDUCTOR DEVICES; ELECTRIC SOLID-STATE DEVICES NOT OTHERWISE PROVIDED FOR
  • H10N—ELECTRIC SOLID-STATE DEVICES NOT OTHERWISE PROVIDED FOR
  • H10N30/00—Piezoelectric or electrostrictive devices
  • H10N30/80—Constructional details
  • H10N30/87—Electrodes or interconnections, e.g. leads or terminals
  • H10N30/872—Interconnections, e.g. connection electrodes of multilayer piezoelectric or electrostrictive devices
• • H—ELECTRICITY
  • H10—SEMICONDUCTOR DEVICES; ELECTRIC SOLID-STATE DEVICES NOT OTHERWISE PROVIDED FOR
  • H10N—ELECTRIC SOLID-STATE DEVICES NOT OTHERWISE PROVIDED FOR
  • H10N30/00—Piezoelectric or electrostrictive devices
  • H10N30/01—Manufacture or treatment
  • H10N30/06—Forming electrodes or interconnections, e.g. leads or terminals
  • H10N30/063—Forming interconnections, e.g. connection electrodes of multilayered piezoelectric or electrostrictive parts
• • H—ELECTRICITY
  • H10—SEMICONDUCTOR DEVICES; ELECTRIC SOLID-STATE DEVICES NOT OTHERWISE PROVIDED FOR
  • H10N—ELECTRIC SOLID-STATE DEVICES NOT OTHERWISE PROVIDED FOR
  • H10N30/00—Piezoelectric or electrostrictive devices
  • H10N30/50—Piezoelectric or electrostrictive devices having a stacked or multilayer structure
• • H—ELECTRICITY
  • H10—SEMICONDUCTOR DEVICES; ELECTRIC SOLID-STATE DEVICES NOT OTHERWISE PROVIDED FOR
  • H10N—ELECTRIC SOLID-STATE DEVICES NOT OTHERWISE PROVIDED FOR
  • H10N30/00—Piezoelectric or electrostrictive devices
  • H10N30/80—Constructional details
  • H10N30/85—Piezoelectric or electrostrictive active materials
  • H10N30/857—Macromolecular compositions
• • H—ELECTRICITY
  • H10—SEMICONDUCTOR DEVICES; ELECTRIC SOLID-STATE DEVICES NOT OTHERWISE PROVIDED FOR
  • H10N—ELECTRIC SOLID-STATE DEVICES NOT OTHERWISE PROVIDED FOR
  • H10N30/00—Piezoelectric or electrostrictive devices
  • H10N30/80—Constructional details
  • H10N30/87—Electrodes or interconnections, e.g. leads or terminals
  • H10N30/877—Conductive materials
  • H10N30/878—Conductive materials the principal material being non-metallic, e.g. oxide or carbon based

Definitions

• the invention relates to a transducer comprising a laminate with a film of a dielectric polymer material arranged between first and second layers of an electrically conductive material.
• a conductor facilitates application of an electrical potential between the first and second layers, and due to the electrical field which may arise, the polymer material is deformed by the first and second layers when they are moved to or from each other.
• transducers An electrical potential difference between two electrodes located on opposite surfaces of an elastomeric body generates an electric field leading to a force of attraction. As a result, the distance between the electrodes changes and the change leads to compression of the elastomeric material which is thereby deformed.
• Such structures can be used for making transducers for various purposes. When implemented as actuators they are sometimes referred to as "artificial muscles" due to certain similarities with a muscle. They can also be used as sensors for sensing strain, deflection, temperature variation, pressure etc., or they can be used as generators for converting mechanical energy to electrical, sometimes referred to as energy harvesting.
• transducers or polymer transducers are sometimes referred to as electrostatic energy.
• US 6,376,971 discloses a compliant electrode which is positioned in contact with a polymer in such a way, that when applying a potential difference across the electrodes, the electric field arising between the electrodes contracts the electrodes against each other, thereby deflecting the polymer.
• the connector which connects the electrode to a power source must constantly follow the movement of the electrode.
• the connector is made sufficiently long to avoid that the electrode constitutes a constraint for the free movement of the polymer and thus reduces the efficiency of the device.
• the long connectors may get entangled or be in the way.
• the invention provides a transducer comprising conductors and a laminate, the laminate comprising a film of a dielectric polymer material arranged between first and second electrodes, and each electrode being in electrically conductive
• At least one of the conductors is an elastically deformable conductor comprising a compliant core which is electrically conductive, the core being enclosed in a containment having elastomeric properties.
• the invention provides connectivity with a connector which can be elastically deformable to match the elastic deformability of the film, and the risk of fatigue is reduced or completely avoided at least with regard to the conductive core. Accordingly, the connector may follow the movement of the electrode without limiting the movement of the film.
• conductive is herein meant that it can conduct an electrical current, e.g. having an ohmic resistivity below 10 "4 ⁇ -cm, such as a resistivity in the range of that of aluminium, copper, silver, or alloys containing such metals.
• the dielectric material of the film may be a polymer, e.g. an elastomer, such as a silicone elastomer, such as a weak adhesive silicone.
• a suitable elastomer is Elastosil RT 625, manufactured by Wacker-Chemie.
• Elastosil T 622 or Elastosil RT 601, also manufactured by Wacker-Chemie may be used.
• other kinds of polymers may be chosen.
• the dielectric material should have elastomer-like properties, e.g. in terms of elasticity.
• the dielectric material should be deformable to such an extent that the composite is capable of deflecting and thereby pushing and/or pulling due to deformations of the dielectric material.
• the electrodes may have a thickness in the range of 0.01-0.1 pm, and the film may have a thickness between 10 pm and 200 ⁇ , such as between 20 pm and 150 pm, such as between 30 pm and 100 pm, such as between 40 pm and 80 pm.
• the electrodes may have a resistivity which is less than 10 "4 ⁇ -cm. By providing an electrode having a very low resistivity the total resistance of the electrodes will not become excessive, even if very long electrodes are used.
• the electrodes may be made from a metal or an electrically conductive alloy, e.g. from a metal selected from a group consisting of metals, such as silver, gold, and nickel.
• the electrodes may be applied to the dielectric film using standard commercial physical vapour deposition (PVD) techniques.
• PVD physical vapour deposition
• the dielectric material of the film may have a resistivity which is larger than 10 10 ⁇ -cm.
• the resistivity of the dielectric material is much higher than the resistivity of the electrodes, preferably at least 10 14 -10 18 times higher.
• the containment may be made from an elastomer, or from a material having elastomeric properties, i.e. a material having characteristics similar to an elastomer with regard to electrical conductivity and elasticity.
• the compliant core may comprise fluid, grease, gel, elastomer, powder, pasta, or mixtures hereof, such as a metal powder in a gel.
• the laminate may comprise a film of a dielectric material having a first surface and second surface, at least the first surface comprising a surface pattern of raised and depressed surface portions.
• a first electrically conductive layer is deposited onto the surface pattern and forms an electrode thereon.
• the electrode has a corrugated shape which renders the length of the electrically conductive layer in a lengthwise direction, longer than the length of the laminate as such in the lengthwise direction.
• the corrugated shape of the electrode thereby facilitates that the laminate can be stretched in the lengthwise direction without having to stretch the electrode in that direction, but merely by evening out the corrugated shape of the electrode.
• the corrugated shape of the electrode may be a replica of the surface pattern of the film.
• the electrode Since the electrode is deposited onto the surface pattern of the film and is formed by the shape thereof, a very precise shape of the corrugation of the electrode can be defined, and an improved compliance towards deformation in a specific direction can be provided by a suitable design of the surface pattern on the film. Accordingly, the laminate can facilitate increased actuation forces, or in general an increased rate of conversion between mechanical and electrical energies, increased lifetime and improved reaction time when the laminate is used in a transducer.
• the compliance of the laminate in the compliant direction may be at least 50 times larger than its compliance in the non-compliant direction, i.e. perpendicularly to the compliant direction.
• the laminate may comprise a multilayer composite e.g. by arranging films each with at least one electrode in a stack and by applying an electrical potential difference between each adjacent electrodes in the stack so that the layers are biased towards each other while they are simultaneously flattened out. Due to the properties of the film, this may bond the layers together.
• the layers may be bonded by an adhesive arranged between each layer.
• the adhesive should preferably be selected not to dampen the compliance of the multilayer structure. Accordingly, it may be preferred to select the same material for the film and adhesive, or at least to select an adhesive with a modulus of elasticity being less than the modulus of elasticity of the film.
• the composite layers in the multilayer composite should preferably be identical to ensure a homogeneous deformation of the multilayer composite throughout all layers, when an electrical field is applied. Furthermore, it may be an advantage to provide the corrugated pattern of each layer either in such a way that wave crests of one layer are adjacent to wave crests of the adjacent layer or in such a way that wave crests of one layer are adjacent to troughs of the adjacent layer.
• the containment may be conductive and may separate the compliant core from the electrode to enable conduction from the core through the containment to the electrode, whereby the containment may be able to protect and retain the core, while at the same time enabling conduction from the core to the electrode.
• the conductor may be formed as an elongated body like a tradition wire.
• the conductor may be formed as a pouch being circular, oval, or of another shape suitable for establishing the electrically communication with one of the electrodes.
• the laminate may be arranged in a spiral configuration and may thereby form a roll with a body extending axially between two end faces.
• the electrodes may have anisotropic stretchability, or anisotropic compliance.
• the anisotropic compliance/stretchablity may be caused by the electrodes which may be formed at a wave shaped surface pattern. This surface pattern may create an electrode with a length in one direction being substantially longer than the length of the laminate as such, and the laminate can therefore be stretched in one direction without stretching the electrode. This provides the compliance in this direction, i.e. the anisotropic stretchablity.
• the lack of compliance in other directions can also be provided by the same electrode because it is substantially less elastically deformable than the film.
• the ratio between a modulus of elasticity of the electrode and a modulus of elasticity of the film may be larger than 200.
• a laminate may in one embodiment be rolled relative to the anisotropic stretchability such that an electrical field causes radial expansion or contraction of the roll.
• the containment may be formed about a contacted one of the end faces.
• the first and second electrodes may each contact a containment at an end face of the roll thereby enabling radial expansion or contraction of the roll in response to an electrical field, i.e. an electrical potential between the two end faces of the roll.
• the laminate may be formed so that the one of the electrodes is formed to an edge of the film such that the electrode extends to the contacted end face, such that an outer surface of the containment may be located in plane with the end face and be in electrical contact with the electrode which is terminated at that end face.
• the other electrode may on the contrary be formed to an edge of the film in the opposite direction such that this electrode extends to the other contacted end face, thereby facilitating contact between the other electrode and the other conductor.
• the two electrodes do only extend to one edge of the film, i.e. to opposite edges so that each of the electrodes is contact with only one conductor.
• an overlapping portion of the electrodes exist where the film can be deformed between the electrodes.
• the compliant core may be in direct contact with a surface of one of the first and second electrodes. This may be facilitated by providing an aperture in the containment, the aperture being arranged at the contacted end face of the roll.
• the laminate may be rolled perpendicular to the anisotropic stretchability, whereby an electrical field causes a lengthwise expansion or contraction of the roll.
• a laminate may be folded along the length of the laminate to have a multi-layer composite with a reduced length.
• the conductance, G (I/V), of the containment may be in the range of 1-50 pet. of the conductance, G, of the compliant core.
• the elastic elongation of the containment may be in the range of 10-200 pet. of the elastic elongation of the film.
• 'elastic elongation' is herein meant, the percentage elongation which can be reached without permanently deforming the polymer material.
• the containment and the film may comprise an identical polymer material.
• the compliant core may comprise a metal which is liquid at room temperature.
• the conductor may thus be manufactured at a lower temperature where the metal is solid to facilitate positioning of the containment so that it encloses the core. Subsequently, the conductor may be arranged at room temperature, whereby the core becomes liquid.
• the compliant core may comprise a material selected from the group consisting of: aluminium, copper, nickel, silver, carbon, mercury, and combinations hereof.
• the core may comprise fluid, grease, gel, elastomer, powder, pasta, or mixtures hereof, such as a metal powder in a gel, or a conductive carbon powder.
• the compliant core may comprise an amorphous alloy, i.e. a non-crystalline alloy. These alloys may contain atoms of significantly different sizes, leading to low free volume in liquid state. Furthermore, these alloys soften and flow upon heating.
• the containment may be tubular with an inner lumen extending in an axial direction.
• the cross-section of the containment may change along the axial direction.
• the cross-section may be substantially circular with an increasing and decreasing area, the outer surface being wave shaped. This may have the advantage, that the containment can be elongated without reducing the cross-sectional area of the inner lumen at the positions it is thinnest. When the conductor is stretched, the containment deforms by reduction of the cross-sectional area at the positions where the containment is thickest so that the cross- sectional area at these positions may be decreased.
• the cross-sectional area may be of any shape, i.e. the containment may have a non-circular cross-section perpendicular to the axial direction.
• the containment may form a plurality of compartments, each compartment enclosing a compliant core. Thereby it may be ensured, that only the compliant core or parts hereof from a single compartment is leaked in case of damage of the containment.
• each compliant core may be in electrical communication with an adjacent compliant core by the conductivity of the containment.
• the containment may contain only the compliant core, e.g. by ensuring that the containment does not contain air bubbles or the like, as such bubbles may hinder or reduce current-carrying along the length of the conductor. Bubbles may especially be a problem during expansion of the conductor, as the cross-sectional area hereof may be decreased during the expansion.
• the transducer may furthermore comprise a control system which is capable of determining an electrical characteristic of the conductor and to determine therefrom, a degree of elongation of the conductor.
• the electrical characteristic may as an example be resistance, capacitance, inductance, or a combination hereof.
• at least one of the conductors may be in electrically conductive communication with one of the electrodes substantially along a compliant direction to enable deflection of the polymer material in response to an electrical field.
• the conductor itself may be expanded and contracted together with the laminate.
• the conductor may be in electrically conductive communication along the compliant direction when being positioned parallel to the compliant direction and being positioned within +/- 45 degrees to compliant direction.
• the laminate may be rolled along the compliant direction to form a roll such that an electrical field causes radial expansion or contraction of the roll. If the transducer comprises at least one of the conductors in electrically conductive communication with one of the electrodes substantially along a compliant direction, it may thereby be ensured that the conductor does not restrict the movement of the roll, as the elastically deformable conductor may expand and contract together with the laminate.
• the conductor may be connected to a traditional wire.
• a traditional wire is stiff compared to the elastically deformable conductor, stress may occur about the joint due to the concentration of tension. Such stress may weaken the joint.
• the conductor may comprise at least two different portions facilitating functions and having different elastic properties.
• these two portions are referred to as a primary portion and a transition portion.
• the transition portion may facilitate connection of the elastically deformable conductor to a traditional non-elastically deformable wire, and the transition zone may be less elastically deformable than the primary portion.
• the primary portion of the conductor should be understood as the portion of the conductor being adhesively and/or electrically coupled to one of the electrodes. It should further be understood, that primary is not related to size, as the primary portion of the conductor in some embodiments may be larger than the transition zone and in other embodiments may be smaller than the transition zone.
• the transition zone may be formed as an extension hereto.
• a conductor being pouch formed e.g. having a circular shape, may comprise a transition zone formed as a flange along the circumference or a part hereof of the conductor.
• the invention provides a conductor comprising a conductive compliant core enclosed in an elongated containment made from an elastomer, wherein the elastomer is conductive.
• the conductor according to the second embodiment of the invention may comprise any of the features mention above in connection with the first embodiment of the invention, as these features may also be applicable to the conductor of the second aspect of the invention.
• the invention provides a method of making a conductor for an electroactive polymer transducer, the method comprising the steps of:
• Figs, la and lb illustrate an example of a laminate
• Figs. 2a and 2b illustrate an example of a conductor connected to a laminate
• Figs. 3a and 3b illustrate an example of a conductor connected to a laminate
• Figs. 4a and 4b illustrate a transducer comprising a conductor connected to a laminate according to the invention
• Figs. 5a and 5b illustrate two different configurations of a rolled laminate
• Figs. 6a-6d illustrate different embodiments of transducer
• Figs. 7a-7d illustrate the transducers of Figs. 6a-6b with a protective coating
• Figs. 8a and 8b illustrate a transducer comprising a conductor connected to a rolled laminate
• Fig. 9 illustrate a transducer comprising a conductor connected to an alternative embodiment of a rolled laminate
• Fig. 10 illustrates a transducer comprising a conductor comprising a transition zone, the conductor being connected to a rolled laminate
• Fig. 11 illustrates a transducer comprising a conductor comprising a transition zone, the conductor being connected to a laminate
• Fig. 12 and Fig. 13 illustrate conductors
• Figs. 14a-14c illustrate a conductor
• Figs, la and lb illustrate a laminate 1 comprising a film 2 of a dielectric polymer material arranged between first and second electrodes 3, 4.
• the laminate 1 is exposed to zero electrical potential difference
• Fig. lb the laminate 1 is exposed to a high electrical potential difference.
• the film 2 is expanded, while the electrodes 3, 4 are evened out, when exposed to an electrical potential difference.
• the laminate 1 comprises a film 2 made of a dielectric material having an upper and lower surface provided with a pattern of raised and depressed surface portions, thereby forming a designed corrugated profile of the surface.
• An electrically conductive layer has been applied to the upper and lower surface, the electrically conductive material being deposited so that the electrically conductive layer is formed according to the pattern of raised and depressed surface portions, thereby forming a first and second electrode 3, 4 on opposite sides of the film 2.
• the film 2 resembles in some aspects household wrapping film. It has a similar thickness and is comparably pliable and soft. However, it is more elastic than such a film, and has a marked mechanical anisotropy as will be explained in the following.
• the dielectric material may be an elastomer or another material having similar
• the electrodes 3, 4 may even out as the film 2 expands, and recover its original shape as the film 2 contracts along the direction defined by the arrow 5 without causing damage to the electrodes 3, 4, this direction thereby defining a direction of compliance. Accordingly, the laminate 1 is adapted to form part of a compliant structure capable of withstanding large strains.
• the corrugated surface profile is directly impressed or moulded into the dielectric film 2, before the electrically conductive layer is deposited.
• the corrugation allows the manufacturing of a compliant composite using electrode materials of high elastic modulii, e.g. metal electrode. This can be obtained without having to apply pre-stretch or pre-strain to the dielectric film 2 while applying the electrically conductive layer, i.e. the electrodes 3, 4, and the corrugated profile of the finished composite 1 does not depend on strain in the dielectric film 2, nor on the elasticity or other characteristics of the electrodes 3, 4.
• the corrugation profile is replicated over substantially the entire upper and lower surfaces of the film 2 in a consistent manner, and it is possible to control this replication.
• this approach provides the possibility of using standard replication and reel-to- reel coating, thereby making the process suitable for large-scale production.
• the electrodes 3, 4 may be applied to the upper and lower surfaces of the dielectric film 2 using standard commercial physical vapour deposition (PVD) techniques.
• PVD physical vapour deposition
• the laminate 1 shown in Figs, la and lb is designed to have a compliance in the range of the compliance of the film 2 in the direction defined by the arrow 5, and a stiffness in the range of the stiffness of the electrodes 3, 4 in a direction defined by the arrow 6.
• the compliance direction is along the length of the composite 1.
• Figs. 2a and 2b illustrate conductors 7a, 7b connected to a laminate 1, the conductors 7 being in electrically conductive communication with the electrodes 3, 4 to facilitate an electrical potential between the electrodes and thereby enable deflection of the film 2 in response to an electrical field.
• the conductors 7 are connected to the film in the direction where the laminate is constraint, i.e.
• Figs. 3a and 3b illustrate conductors 7a, 7b connected to a laminate 1, the conductors 7 being in electrically conductive communication with the electrodes 3, 4 to facilitate an electrical potential between the electrodes and thereby enable deflection of the film 2 in response to an electrical field.
• the conductors 7 are connected to the laminate 1 in the direction where the laminate is compliant (indicated by the arrow 5).
• the conductors 7 have to be stretchable to be able to follow the deflection of the film 2 in the lengthwise direction, i.e. along the compliance length, when an electrical potential between the electrodes 3, 4 causes the deflection.
• the conductors 7 are made from a soft, stretchable conductive polymer having a resistance, resulting in a high resistance of the system even though the resistance of the electrodes is very low.
• Figs. 4a and 4b illustrate a transducer 8 comprising conductors 7a, 7b connected to a laminate 1 according to the invention.
• the conductors 7 are in electrically conductive communication with the electrodes 3, 4 to facilitate an electrical potential between the electrodes and thereby enable deflection of the film 2 in response to an electrical field.
• the conductors 7 are connected to the laminate 1 in the direction where the laminate is compliant (indicated by arrow 5).
• the conductors 7 comprise a conductive compliant core 9 enclosed in a containment 10 having elastomeric properties. Even though the containment 10 is made from an elastomer with a high resistance, the resulting resistance of the conductors 7 are low due to the low thickness of the containment 10 in combination with the conductive core 9 having a low resistance.
• the core may be made of a fluid or powder, e.g. of carbon powder or a metal powder in a gel. Thus, the containment 10 may encapsulate the compliant core 9.
• Figs. 5a and 5b illustrate two different configurations of a rolled laminate 1.
• the compliance direction (see arrow 5) is along the length of the laminate 1
• the compliance direction of Fig. 5b is across the laminate 1. This is indicated by the thin lines across the composite 1 in Fig. 5a and along the composite 1 in Fig. 5b, which thin lines represent the pattern of raised and depressed surface portions forming the corrugated profile.
• the laminate 1 may be produced in very long lengths, so called “endless” laminates which may be stored as spools as shown in Figs. 5a and 5b. Such semi finished goods may be used for the production of transducers and the like, e.g. actuators.
• Figs. 6a-6d illustrate different embodiments of transducer 8, in which the transducer 8a is the most simple one.
• the transducers 8a-8d all comprise a rolled laminate 1 and conductors 7. Only one conductor 7 is illustrated in the figures, as the other conductor is in electrical conductive communication with an electrode at the other end of the rolled laminate. Only one of the electrodes 3, 4 is illustrated in the figures as only the first electrode 3 is formed to an edge of the film 2 such that the electrode 3 extends to the contacted end face of the rolled laminate, such that an outer surface of the containment 10 (not shown) is located in plane with the end face and is in electrical contact with the electrode 3 being terminated at that end face.
• the other electrode 4 (not shown) is on the contrary formed to an edge of the film 2 in the opposite direction such that this electrode extends to the other contacted end face, thereby facilitating contact between the other electrode 4 and the other conductor (not shown).
• the transducer 8a comprises a conductive core 9 with conductance G, and a rolled laminate 1 comprising a film 2 and an electrode 3.
• the transducer 8b is formed so that a part of the compliant conductive core 9 of the conductor 7 is positioned between the film 2 and the electrode 3 of the rolled laminate 1.
• a non-conductive elastic seal 11 is provided in the gab.
• a conductive containment 10 is provided at the end face of the rolled laminate 1.
• a part of the conductive containment 10 is furthermore positioned in a gab between the film 2 and the electrode 3 of the rolled laminate 1.
• an additional conductive containment 13 is provided at the end face of the rolled laminate 1.
• Figs. 7a-7d illustrate the transducers 8a-8b of Figs. 6a-6b with a protective coating 14 encapsulating the conductor and the end face of the laminate.
• Fig. 8b illustrates a transducer 8 comprising a conductor 7 connected to a rolled laminate 1.
• Fig. 8a illustrates the rolled laminate 1 before connection of the conductor 7.
• the conductor 7 has an elongated structure. Due to the elastical deformbility of the conductor 7, it can be rolled and bended (see Fig. 8b) to ensure electrically conductive communication with an electrode (not shown).
• the laminate is rolled relative to the anisotropic stretchability illustrated by the thin lines such that an electrical field causes radial expansion or contraction of the roll as indicated by the arrows 5. Due to the elastically deformable the conductor 7, it can be ensured that the conductor 7 does not restrict the movement of the roll, as the conductor 7 expands and contracts together with the rolled laminate 1. In order to enable an electrical potential between the electrodes, the conductor 7 is connected to a traditional wire 14 via a joint 15.
• Fig. 9 illustrates another embodiment of a transducer 8 comprising a conductor 7 connected to a laminate 1 being rolled in the lengthwise direction, whereby an electrical field causes a lengthwise expansion or contraction of the roll as indicated by the arrows 5. Due to the elastically deformable conductor 7, the conductor 7 expands and contracts together with the rolled laminate 1.
• the conductor 7 is connected to a traditional wire 14 via a joint 15.
• Fig. 10 illustrates a transducer 8 comprising a conductor 7 and a rolled laminate 1.
• the transducer 8 is similar to the transducer illustrated in Figs. 8a and 8b.
• the conductor 7 is connected to a traditional wire 14 via a joint 15.
• the conductor 7 therefore comprises two different portions, a primary portion 7' and a transition portion 16.
• the transition portion 16 facilitates connection of the elastically deformable conductor 7 to the traditional non-elastically deformable wire 14.
• the transition zone 16 is less elastically deformable than the primary portion 7'.
• the primary portion 7' of the conductor is the portion of the conductor 7 being adhesively and/or electrically coupled to one of the electrodes (not shown).
• Fig. 11 illustrates another embodiment of a transducer 8 comprising a conductor 7 having a transition zone 16 for connection to a traditional wire 14.
• Fig. 12 and Fig. 13 illustrate conductors 7 comprising a compliant core 9 being enclosed in a containment 10.
• the conductor 7 is connected to a traditional wire 14 via a joint 15.
• the transition zone 16 is not shown in these figures.
• the containment 10 comprises two compartments, each comprising a compliant core 9.
• openings are provided in the containment to allow for direct contact between the compliant core 9 and the electrode (not shown).
• Figs. 14a-14c illustrate a conductor 7.
• Figs. 14a and 14b illustrate one example of how to assemble a conductor 7 comprising a compliant core 9 enclosed in a containment with a traditional wire 14 via a joint 15.
• Fig. 14c it is illustrated how the conductor 7 is extended together with the laminate (not shown) in response to an electrical field causing an expansion of the laminate.

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• 2013
  • 2013-02-12 WO PCT/DK2013/000014 patent/WO2013120493A1/en active Application Filing
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