Abstract: A device and to a method of producing a device, wherein the method includes, inter alia, providing a substrate and generating at least two mutually spaced-apart cavities within the substrate. In accordance with the invention, each cavity has a depth of at least 50 ?m. The cavities are filled up with magnetic particles, wherein the magnetic particles enter into contact with one another at points of contact, and wherein cavities are formed between the points of contact. At least some of the magnetic particles are connected to one another at their points of contact, specifically by coating the magnetic particles, wherein the cavities are at least partly penetrated by the layer produced in the coating process, so that the connected magnetic particles form a magnetic porous structure.

Abstract: A method of producing a device includes providing a substrate which has a recess. A multitude of loose particles is introduced into the recess. A first portion of the particles is coated by using a coating process having a depth of penetration which extends from an opening of the recess, along a direction of depth, and into the recess, so that the first portion is connected to form a solidified porous structure. The depth of penetration of the coating process which extends into the recess is set such that a second portion of the particles is not connected by means of the coating, and such that the solidified first portion of the particles is arranged between the second portion of the particles and surroundings of the recess. According to the invention, the second portion of the particles is at least partly removed from the recess.

Abstract: The invention relates to a component, comprising a carrier made of a structurable material with at least one continues opening which is closed by a porous membrane, characterized in that the porous membrane protrudes from the surface of the component surrounding the continuous opening. In some embodiments, the component further comprises a carrier substrate, wherein a side of the carrier substrate which faces the component and the opposite side of the component preferably form a fluid channel, wherein the at least one continuous opening of the carrier preferably communicates on its open side with the fluid channel. The component according to the invention is suitable for the installation and electrochemical measuring of transmembrane proteins, preferably in lipid bilayers. The invention also proposes different methods for producing the component.

Abstract: An apparatus includes a substrate having a recess and a multitude of particles arranged in the recess. A first portion of the particles is joined to a porous structure by means of a coating. A second portion of the particles is not joined by means of the coating. The first portion of the particles is arranged closer to an opening of the recess than the second portion of the particles so that a leaking of the second portion of the particles from the recess through the opening is prevented.

Abstract: A method for manufacturing a device having a three-dimensional magnetic structure includes applying or introducing magnetic particles onto or into a carrier element. A plurality of at least partly interconnected cavities are formed between the magnetic particles, which contact one another at points of contact, by coating the arrangement of magnetic particles and the carrier. The cavities are penetrated at least partly by the layer generated when coating, resulting in the three-dimensional magnetic structure. A conductor loop arrangement is provided on the carrier or a further carrier. When a current flows through the conductor loop, an inductance of the conductor loop is changed by the three-dimensional magnetic structure, or a force acts on the three-dimensional magnetic structure or the conductor loop by a magnetic field caused by the current flow, or when the position of the three-dimensional magnetic structure is changed, a current flow is induced through the conductor loop.

Abstract: A micro-electro-mechanical system includes a deflectable actuator plate and an abutment area. An integral piezoelectric functional layer of the deflectable actuator plate is configured across an area APS of the actuator plate. The deflectable actuator plate is configured to effect a hollow warp in at least a controlled or non-controlled state, wherein the abutment area is disposed facing a hollow side of the deflectable actuator plate defined by the hollow warp. The deflectable actuator plate is configured to provide, in the state in which the same effects the hollow warp, mechanical contact between the deflectable actuator plate and the abutment area. In the other state, the deflectable actuator plate is disposed spaced apart from the abutment area.

Abstract: The invention relates to a method for producing a three-dimensional structure. The method according to the invention comprises the following steps: applying to or introducing into a carrier element (1; 7; 16) particles (2), a plurality of at least partially interlinked cavities being formed between the particles (2) and the particles (2) coming into contact in points of contact, and interconnecting the particles (2) in the points of contact by coating the system consisting of particles and the carrier element, the coat (4) produced during coating penetrating the cavities at least to some extent. The method according to the invention allows the production of three-dimensional structures with little effort.

Abstract: The invention relates to a method for producing a three-dimensional structure. The method according to the invention comprises the following steps: applying to or introducing into a carrier element (1; 7; 16) particles (2), a plurality of at least partially interlinked cavities being formed between the particles (2) and the particles (2) coming into contact in points of contact, and interconnecting the particles (2) in the points of contact by coating the system consisting of particles and the carrier element, the coat (4) produced during coating penetrating the cavities at least to some extent. The method according to the invention allows the production of three-dimensional structures with little effort.

Abstract: The present invention relates to a micromechanical HF switching element, in which a freestanding movable element is situated above a metallic surface on a substrate in such way that it is drawn to the metallic surface, to which a dielectric layer is applied, by applying an electrical voltage between the metallic surface and the movable element. The present invention also relates to a method for producing micromechanical HF switching elements of this type, in which the dielectric layer is deposited on the metal surface. The present method is distinguished in that a piezoelectric AlN layer having a columnar, polycrystalline structure and a texture is deposited on the metallic surface as the dielectric layer. Significantly reduced charging of the dielectric material and increased long-term stability of the switching element are achieved by the present method and the HF switching element thus produced.

Abstract: A device is disclosed for pipetting a liquid, comprising a pipette body enclosing a pipette volume, into which a fluid medium can be placed and in which an actuator that controllably displaces the medium in the pipette volume is provided, as well as a pipette tip, which can be connected to the pipette volume in a fluid-tight manner. The present invention is distinguished by the pipette volume and the pipette tip being connected via a fluid-tight connecting means directly or indirectly to each other in such a manner that the pipette tip is moveable relative to the pipette volume.

Abstract: A pipette system including a pipette capillary tube and an actuator, with the actuator serving to set the position of a phase boundary between a system medium and a second medium in the pipette capillary is described. A sensor element is also provided for measuring the position of the phase boundary, in such a way that the actuator is controlled by a regulating element in response to an output signal from the sensor element.

Abstract: Disclosed is a device for pipetting a liquid, comprising a pipette body enclosing a pipette volume, into which a fluid medium can be placed and in which an actuator that controllably displaces the medium in the pipette volume is provided, as well as a pipette tip, which can be connected to the pipette volume in an fluid-tight manner.

Abstract: The present invention relates to a micromechanical HF switching element, in which a freestanding movable element (5) is situated above a metallic surface (2) on a substrate (1) in such way that it is drawn to the metallic surface (2), to which a dielectric layer (3) is applied, by applying an electrical voltage between the metallic surface (2) and the movable element (5). The present invention also relates to a method for producing micromechanical HF switching elements of this type, in which the dielectric layer (3) is deposited on the metallic surface (2). The present method is distinguished in that a piezoelectric AlN layer having a columnar, polycrystalline structure and a texture is deposited on the metallic surface (2) as the dielectric layer (3). Significantly reduced charging of the dielectric material and increased long-term stability of the switching element are achieved by the present method and the HF switching element thus produced.

Abstract: A sensor element for electrically measuring the position of liquid levels, comprising a substrate (2) and a plurality of electrodes (3) that can be contacted individually and that are mounted on the substrate, characterized in that the electrodes comprise sensor-active partial electrodes (5) that are networked with electrical connections (7), with the partial electrodes of two respective electrodes always being positioned opposite one another, separated by a distance, as partial electrode pairs (11) and with the electrode pairs (8) thus formed recurring periodically over the length of the sensor. Quasi-digital measuring methods are derived from the behavior of the impedance of the electrode pairs, whereby the liquid level is measured by detecting a conductivity boundary in a capillary filling.

Abstract: What is proposed here is a pipette system comprising a pipette capillary tube (1) and an actuator (9), with the actuator serving to set the position of a phase boundary (13) between a system medium (3) and a second medium in the pipette capillary and with a sensor element (18) being provided for measuring the position of the phase boundary, in such a way that the actuator is controlled by a regulating element (12) in response to an output signal from the sensor element.

Abstract: A micromechanical pump has a membrane (2) positioned above a substrate (1). The substrate is provided with a cavity (8) which is formed in an endlessly continuous shape (e.g., circular) to provide a channel for a drive fluid. A cover (9) is positioned above the substrate with the membrane being between the substrate and cover. The cover is provided with an inlet (11) and outlet (10). Electrodes (3, 4) are provided around the floor of the cavity. The electrodes are selectively actuated so as to attract selected areas of the membrane resulting in a gap forming between the cover and the selected areas of the membrane. The areas of the membrane above the non-selected electrodes form a seal with the cover. By selectively actuating the electrodes a peristaltic pumping action results in a pumped fluid traveling from the inlet, through the gaps and out the outlet.

Abstract: A valve arrangement including a micro-valve at an intake opening and a fuer valve at an output opening of a chamber connecting to a pressure-variable switching member, the valves being structured to maintain a closed state by an applied pressure difference. At least the micro-valve is provided with a closure member which can be energized to affect a change-over from one state to another. No energy is required to maintain the changed-over state.

Abstract: An ultra-miniaturized surface structure with controllable adhesion having extremely miniaturized (in the sub atomic range) planar electrode strips applied to the surface to which high frequency pulse trains may be applied to generate progressive or stationary standing waves. The electrodes in themselves are combined with dielectric insulating materials with controlled bio-compatibility. The type of electric drive, together with the properties of the surface layers that cover the electrodes, determines the adhesion properties of the surface to a large extent regardless of the used base material. Particle movement is gently influenced, so that for the first time it becomes possible to influence particles in highly physiological nutritive solutions.

Abstract: The present invention relates to a microvalve usable primarily as a pilot lve in pneumatic controls. The prior art solenoid valves used in this field can be miniaturized only at considerably high cost. The microvalve of the invention consists of a first part (1), on the pressure side, with a diaphragm structure (3) as the movable closing component and a second part (2) with an outlet aperture (7) and a seat (5). The diaphragm structure has heating elements and is coated on one side with a material with differing coefficients of heat expansion, in such a way that heating causes the diaphragm to bend against the pressure applied on it. At least one of the two parts has a recess (6) of defined depth arranged in such a way that with the valve closed hollows are formed which are heated by the heating elements. The microvalve described can economically produced with semiconductor technology means and has improved switching properties on account of its combined thermo-mechanical/thermo-pneumatic method of operation.