Abstract: This invention relates to a method of selection of an electrocatalyst array for a desired product outcome. The method comprises exposing an electrocatalyst system to an active agent dissolved or suspended in a conductive solution; and applying a voltage to the electrocatalyst system. The voltage sufficient to cause a multi-electron oxidation or multi-electron reduction of the active species; the electrocatalyst system comprises a counter electrode; and an electrocatalyst array. The array comprising a support substrate; uniformly sized surface structures protruding from a surface of the support substrate; the uniformly sized surface structures have edges and/or apices comprising a catalyst.

Abstract: An array includes a support substrate, surface structures protruding from a surface of the support substrate formed from or coated with a first material, a second material deposited on at least some of the surface structures such that the second material is in contact with the first material; and wherein the first material, the second material or the first and second material is conducting or semiconducting, and wherein the first and second material at least partially form a composite.

Abstract: This invention relates to a method of selection of an electrocatalyst array for a desired product outcome. The method comprises exposing an electrocatalyst system to an active agent dissolved or suspended in a conductive solution; and applying a voltage to the electrocatalyst system. The voltage sufficient to cause a multi-electron oxidation or multi-electron reduction of the active species; the electrocatalyst system comprises a counter electrode; and an electrocatalyst array. The array comprising a support substrate; uniformly sized surface structures protruding from a surface of the support substrate; the uniformly sized surface structures have edges and/or apices comprising a catalyst.

Abstract: Disclosed are electrode arrays and methods of focusing charge density (voltage or current) at a functional surface on electrode arrays. An example method comprises: a. providing an electrode array comprising: i. a support substrate; ii. at least one surface structure protruding from an upper surface of the support substrate wherein the surface structure includes an electrode layer; iii. a functional surface on the electrode layer, wherein the functional surface is on an upper portion of the at least one surface structure and wherein the functional surface is adapted to contact an active species in a conductive solution; b. exposing the surface structure to the conductive solution comprising an active species, in which a counter electrode is positioned; c. establishing a current or voltage between the functional surface on the electrode layer and the counter electrode such that the charge density is focussed at the functional surface on the electrode layer.

Abstract: A method of forming a material includes presenting a formable material to a space between opposing forming surfaces of opposed forming tools from whence said material is carried as said opposing forming surfaces advance in a machine direction. The method includes pressurising, as said opposing forming surfaces advance, said material between said opposing forming surfaces in a reduced space between said opposing forming surfaces defining at least in part a pressure forming zone, said reduced space between said opposing forming surfaces being maintained constant until a form of at least one of said opposing forming surfaces is profiled into said material and is retainable thereon. The method also includes releasing the profiled material from between the said opposing forming surfaces, as the space of the pressure forming zone increases between said opposing forming surfaces as the opposing forming surfaces advance.

Abstract: A method of forming a material includes presenting a formable material to a space between opposing forming surfaces of opposed forming tools from whence said material is carried as said opposing forming surfaces advance in a machine direction. The method includes pressurising, as said opposing forming surfaces advance, said material between said opposing forming surfaces in a reduced space between said opposing forming surfaces defining at least in part a pressure forming zone, said reduced space between said opposing forming surfaces being maintained constant until a form of at least one of said opposing forming surfaces is profiled into said material and is retainable thereon. The method also includes releasing the profiled material from between the said opposing forming surfaces, as the space of the pressure forming zone increases between said opposing forming surfaces as the opposing forming surfaces advance.

Abstract: A method of forming a material includes presenting a formable material to a space between opposing forming surfaces of opposed forming tools from when said material is carried as said opposing forming surfaces advance in a machine direction. The method includes pressurizing, as said opposing forming surfaces advance, said material between said opposing forming surfaces in a reduced space between said opposing forming surfaces defining at least in part a pressure forming zone, said reduced space between said opposing forming surfaces being maintained constant until a form of at least one of said opposing forming surfaces is profiled into said material and is retainable thereon. The method also includes releasing the profiled material from between the said opposing forming surfaces, as the space of the pressure forming zone increases between said opposing forming surfaces as the opposing forming surfaces advance.

Abstract: This invention relates to methods for forming a polymer, including continuously depositing a polymer extrudate that is above its glass transition temperature onto a lower molding surface of a first mold in a manner that reduces shear stress in the polymer extrudate, heating the lower molding surface to maintain the polymer extrudate above the glass transition temperature, applying an upper molding surface of a second mold to at least the exposed upper surface of the polymer, allowing the polymer to transition to below the glass transition temperature while within or between the upper and lower molding surfaces, and providing heat sinks spaced relative to each other through the pressure forming zone, wherein a heat sink more advanced through the pressure forming zone is controlled to a lower temperature to progressively reduce the temperature of the polymer as it advances through the pressure forming zone.

Abstract: This invention relates to methods for forming a polymer, including continuously depositing a polymer extrudate that is above its glass transition temperature onto a lower moulding surface of a first mould in a manner that reduces shear stress in the polymer extrudate, heating the lower moulding surface to maintain the polymer extrudate above the glass transition temperature, applying an upper moulding surface of a second mould to at least the exposed upper surface of the polymer, allowing the polymer to transition to below the glass transition temperature while within or between the upper and lower moulding surfaces, and providing heat sinks spaced relative to each other through the pressure forming zone, wherein a heat sink more advanced through the pressure forming zone is controlled to a lower temperature to progressively reduce the temperature of the polymer as it advances through the pressure forming zone.

Abstract: A method of forming a material includes presenting a formable material to a space between opposing forming surfaces of opposed forming tools from whence said material is carried as said opposing forming surfaces advance in a machine direction. The method includes pressurising, as said opposing forming surfaces advance, said material between said opposing forming surfaces in a reduced space between said opposing forming surfaces defining at least in part a pressure forming zone, said reduced space between said opposing forming surfaces being maintained constant until a form of at least one of said opposing forming surfaces is profiled into said material and is retainable thereon. The method also includes releasing the profiled material from between the said opposing forming surfaces, as the space of the pressure forming zone increases between said opposing forming surfaces as the opposing forming surfaces advance.

Abstract: The present invention relates to method of forming a material, including the steps of, presenting a formable material to a space from where the material can be carried by and/or between opposing surfaces of the space, as the opposing surfaces advance in an advancing direction. Also pressurising, as the opposing surfaces advance, the material between the opposing surfaces in a reduced space between the opposing surfaces defining at least in part a pressure forming zone. The reduced space between the opposing surfaces being maintained at least substantially constant until such time as the form of at least one of the opposing surfaces is profiled into the material and is retainable thereon. Thereafter releasing the now profiled material from between the opposing surfaces, as the space increases between the opposing surfaces as the surfaces advance.

Abstract: A forming apparatus for forming a formable material. Each forming tool of a second forming tool set is adapted to co-act with one or more forming tools of a first forming tool set, or vice versa, to form a co-acting forming tool in a pressure forming zone. There is a first forming tool set guide or guides about which the first forming tool set can be moved about a first circuit. There is also a second forming tool set guide or guides about which the second forming tool set can be moved about a second circuit. A drive drives the tools in a machine direction. At least on part of the circuit, adjacent forming tools of one the forming tool sets are movably supported such that the only relative movement of the adjacent forming tools is towards or away from the forming tools of the other forming tool set.

Abstract: The present invention relates to method of forming a material, including the steps of, presenting a formable material to a space from where the material can be carried by and/or between opposing surfaces of the space, as the opposing surfaces advance in an advancing direction. Also pressurising, as the opposing surfaces advance, the material between the opposing surfaces in a reduced space between the opposing surfaces defining at least in part a pressure forming zone. The reduced space between the opposing surfaces being maintained at least substantially constant until such time as the form of at least one of the opposing surfaces is profiled into the material and is retainable thereon. Thereafter releasing the now profiled material from between the opposing surfaces, as the space increases between the opposing surfaces as the surfaces advance.

Abstract: This invention relates to methods for forming polymer(s) including heating of a polymer to be formed to a temperature above its glass transition temperature, continuously depositing (preferably by flowing or laying) the polymer onto a moulding surface (herein the “lower moulding surface”) of a first mould, (preferably in a manner that reduces, eliminates or minimises shear stress or other stress in the polymer so deposited), the polymer remaining above the glass transition temperature, applying a moulding surface (herein the “upper surface”) of the polymer while the polymer remains at a temperature above the glass transition temperature, and allowing the polymer to transition to below the glass transition temperature while within or between the upper and lower moulding surfaces, wherein the polymer is removed from the moulding surfaces. Apparatus is also provided.

Abstract: The application seeks to eliminate errors introduced by bearings and supports. It does so by integrating the drive means, in the form of a piezoelectric actuator, into the bearing or support. Thus the bearing no longer acts against the drive means, eliminating errors. It also describes a drive mechanism for elongate prismatic objects (140). The mechanism uses piezoelectric drives (148) and achieves very high accuracy of positioning with minimal backlash etc, whilst occupying only a small volume. This makes it suitable for use in electro-discharge machining and electro-discharge texturing operations where one or more wire electrodes (140) need to be positioned accurately with respect to a workpiece and maintained in that relative position as the workpiece erodes and the electrode (140) is consumed.

Abstract: A network-field interface, termed an NFI, is intended for digitally interfacing at least one host computer on a network to at least one field device. The network operates with a predetermined communications protocol including READ and WRITE services. The NFI comprises I/O ports for connection to the field devices, a modem to facilitate communication between the network and the interface, a CPU, volatile and non-volatile memory accessible to both the modem and the CPU, and program modules resident in the memory. The program modules are executable by the CPU to map the READ and WRITE services of the network onto the NFI's I/O ports. In this way the host computer is able to READ and WRITE directly to the I/O ports through the modem.