Abstract: The present invention relates to devices for efficient transport, transfer and movement of fluids. In particular, the invention provides fluidic micro-structures for controlled transport and movement of liquids in devices for analytical and other purposes. Devices of the invention include one or more features that can enhance performance of the fluid transfer, referred to as a pre-shooter stop, a butterfly structure, a cascade structure, a waste chamber inlet, a capillary driven sample inlet chamber, a capillary stop structure, a bifurcation flow-through structure, and a hydrophobic vent.

Abstract: A microstructured separating device, especially for separating liquid components from a particle-containing liquid, comprising the following features: at least one transport channel for transport of the liquid in a given transport direction; at least one separating area at a branch point of the transport channel which is adjoined by a side channel through which a partial flow of the liquid from the transport channel is diverted; a microstructure in the separating area which keeps larger particles of the liquid out of the separating area and which slows down the transport of smaller particles in the separating area.

Abstract: The invention relates to a microfluidic switch for stopping a liquid flow during a time interval with the following features: the switch has at least one first channel and at least one second channel; the first channel and the second channel have a common end area; the first channel in the end area has a stopping mechanism for stopping of a liquid flow flowing in the first channel; the stopping mechanism can be controlled by means of a liquid flow flowing in the second channel for continuing the liquid flow in the first channel. Transport in the first and the second channel takes place advantageously by the capillarity acting in the channel.

Abstract: The invention relates to a microfluidic arrangement for metering one or more first metered amounts of liquid (A) and for separating the latter from a second amount of liquid (B), having the following features: the arrangement has a first channel and one or more one or more second channels; the first channel has one inlet and one outlet; in the area of the outlet the arrangement has a capillarity, which is greater than or equal to the capillarity in the area of the inlet; the one or more second channels branch off from the first channel at one or more branch points; the one or more second channels have a greater capillarity than the first channel at the branch points; and the one or more second channels have a predetermined volume. In the arrangement as depicted in the invention a liquid is transported in the first channel from the inlet to the outlet.

Abstract: Device for parallel metering of a liquid with the following features:

Abstract: The present invention relates to devices for efficient transport, transfer and movement of fluids. In particular, the invention provides fluidic micro-structures for controlled transport and movement of liquids in devices for analytical and other purposes. Devices of the invention include one or more features that can enhance performance of the fluid transfer, referred to as a pre-shooter stop, a butterfly structure, a cascade structure, a waste chamber inlet, a capillary driven sample inlet chamber, a capillary stop structure, a bifurcation flow-through structure, and a hydrophobic vent.

Abstract: A microliter liquid sample, particularly a biological sample, is analyzed in a device employing centrifugal and capillary forces. The sample is moved by capillary forces into one or more metering wells which define the amount of said sample to be analyzed in subsequent steps. The defined amount of the sample is transferred from the metering wells to one or more conditioning and reagent wells for measuring the amount of an analyte contained in each metered amount of the sample.

Abstract: A microfluidic device provides separation of particles in a liquid sample, particularly, separation of a sample of whole blood into its components for further analysis. Separation into red blood cells and plasma occurs within a few seconds after the blood sample has been transferred into a separation chamber with the application of centrifugal force of less than one up to about five times gravity. With the application of greater force measurement of hematocrit is possible.

Abstract: The device (10) for the stepwise transport of liquid, particularly of sample liquid to be analyzed, through several reaction chambers located in series in terms of flow while utilizing capillary forces comprises at least one channel (14) through which liquid is transportable on the basis of capillary forces. Further, the device (10) comprises at least two closed vent holes (38,40,42) which are in fluid communication with the channel (14) at connection sites (22,24,26) spaced from each other along the channel (14). The connection sites (22,24,26) divide the channel (14) into several channel sections (44,46,48). The fluid connections between a respective channel section (44,46,48) and the vent holes (38,40,42) allocated thereto can be opened separately.

Abstract: A fluid can be discontinuously atomized with an atomizer of the present invention. The atomizer can include a helical spring, disk spring or gas spring, acting as a pressure spring, as an energy storage device, a cylinder, piston, two ducts and two valves. Atomization can be initiated manually by triggering a locking mechanism. The energy storage device can be disposed outside a storage container for the fluid. The energy storage device can be provided mechanical energy manually. Via the piston, the stored energy can exert pressure onto the fluid in the cylinder, which ranges from 1 MPa to 5 MPa (10 bar to 50 bar). Distribution of the droplet size in the atomized jet can be independent from the level of experience and behavior of the person actuating the atomizer, and can be adjusted in a reproducible manner. The mean droplet diameter can be smaller than about 50 micrometers. The mass flow of the fluid through the nozzle can be less than about 0.4 g/s.

Abstract: A hook and loop fastener is disclosed for the pockets of articles and clothing such as coats, shirts and blouses comprising a hook fastener part, a loop fastener part and a deactivation flap which is attached to an article of clothing for being inserted between the hook fastener part and the loop fastener part.

Abstract: A micro-liter liquid sample, particularly a biological sample, is analyzed in a device employing centrifugal and capillary forces. The sample is moved through one or more sample wells arrayed within a small flat chip via interconnecting capillary passageways. The passageways may be either hydrophobic or hydrophilic and may include hydrophobic or hydrophilic capillary stops.

Abstract: An inkjet printhead containing at least one ink channel communicating with a nozzle and defined between two opposed side walls; a membrane interconnecting the side walls; and actuating elements arranged adjacent to the membrane for deflecting the same, wherein the side walls and the membrane are formed by a one-piece member.

Abstract: An inkjet printhead containing at least one ink channel communicating with a nozzle and defined between two opposed side walls; a membrane interconnecting the side walls; and actuating elements arranged adjacent to the membrane for deflecting the same, wherein the side walls and the membrane are formed by a one-piece member.

Abstract: It is known to thermally weld bodies made of plastic without or with use of an auxiliary substance (adhesive), where the welding temperature is above the glass transition temperature of the plastic.

Abstract: The present invention relates to devices for efficient transport, transfer and movement of fluids. In particular, the invention provides fluidic micro-structures for controlled transport and movement of liquids in devices for analytical and other purposes. Devices of the invention include one or more features that can enhance performance of the fluid transfer, referred to as a pre-shooter stop, a butterfly structure, a cascade structure, a waste chamber inlet, a capillary driven sample inlet chamber, a capillary stop structure, a bifurcation flow-through structure, and a hydrophobic vent.

Abstract: A hook and loop fastener is disclosed for the pockets of articles and clothing such as coats, shirts and blouses comprising a hook fastener part, a loop fastener part and a deactivation flap which is attached to an article of clothing for being inserted between the hook fastener part and the loop fastener part.

Abstract: In a method for joining two or more solid parts, a foil is provided between the two parts, the foil is heated to an elevated temperature by means of a thermode such that it becomes soft, and then the foil is cooled down below the elevated temperature, thus providing a permanent connection. The method can be used for bonding a gas-permeable membrane to a housing such as to produce a liquid chromatography degasser. The bonding method ensures that no unwanted substances are released when liquid comes into contact with the bonding region.

Abstract: Liquid components are separated from a liquid using separation devices, such as filters and membranes, in which capillary forces, which retain the liquid component to be separated in the separation device, are effective. If the amount of liquid is very small, it can be very difficult to remove the liquid component to be separated in the separation device in a free and unchanged form. This process step is simplified or facilitated by a wedge-shaped cut-out at an exit end of the capillary or in a columnar body which is in contact with an exit end of the capillary. A radius of curvature of a wedge edge is smaller than a radius of the capillary. A base side of the wedge-shaped cut-out is adjacent to a collecting chamber in which the separated-off liquid component is collected, and in which the capillary forces are smaller than interfering forces in the capillary itself.

Abstract: An apparatus for degassing liquids comprises a cavity through which liquid is conducted, with gas being removed from the liquid through at least one of the limiting faces of the cavity by providing on the side of the face distal to the cavity a smaller pressure than within the cavity. The apparatus is characterized in that the limiting face between the cavity and the region having reduced pressure compared to the cavity is formed by at least one thin membrane, having a thickness of less than about 10 micrometers, and in that a porous support structure for supporting the membrane is provided. The degasser can be miniaturized and integrated into a liquid chromatograph.