A high-pressure switching valve includes a stator and a rotor. The stator includes a plurality of ports where each port is connected at one end to a port connection and having at another end a predetermined port opening cross section at a stator end face of the stator. The rotor includes a rotor end face and at least one or a plurality of grooves. The rotor can be configured to have a rotary position with respect to the stator where two predetermined port opening cross sections connect to one of the grooves in a pressure-tight manner. The rotor and the stator can be pressed together in a sealing manner at the rotor end face and the stator end face in regions away from the port opening cross sections and the at least one or a plurality of grooves. The rotor and the stator each include a hard material. The rotor can be configured to wobble or tilt with respect to a rotational axis of the rotor.

A preparative chromatograph system includes a sample injector (10) that injects a sample into a separation flow path (8) through which a mobile phase flows, a separation column (12) that is provided on the separation flow path (8) and is to separate a sample injected into the separation flow path (8) into components, a detector (14) that is provided at a position farther downstream than the separation column (12) on the separation flow path (8) and is to detect sample components obtained by separation in the separation column (12), a collector (18, 18′) having a plurality of collection containers (22) for collecting part of an eluate eluted from the separation column (12) and a switch mechanism (20, 30, 32) configured to be capable of selectively connecting a downstream end of the separation flow path (8) to any one of the collection containers (22), a collection setter (26) configured to set a portion, to be collected in each of the collection containers (22), of an eluate eluted from the separation column (12) using a pre-acquired chromatogram of a sample, and a collection setter (26) configured to be capable of setting a portion, including a sample component, of an eluate eluted from the separation column (12), and a portion, between two sample components that are adjacent to each other on the chromatogram, of an eluate eluted from the separation column (12), as the portion to be collected, and a controller (28) configured to control an operation of the switch mechanism (20, 30, 32) of the collector (18, 18′) and collect the portion, which is to be collected and is set by the connection setter (26), in the predetermined collection container (22).

A fluidic valve for a sample separation apparatus for separating a fluid, wherein the fluidic valve comprises a stack of connected layer structures, a first conduit within the stack, a second conduit within the stack, a movable body within the stack, and an actuator configured for actuating the movable body to selectively bring the movable body into a flow enabling configuration in which flow of fluid between the first conduit and the second conduit is enabled, or into a flow disabling configuration in which flow of fluid between the first conduit and the second conduit is disabled.

A sample dispatcher is disclosed and is configured for individually introducing a plurality of portions of one or more sample fluids into a flow of a mobile phase of a liquid separation system. The liquid separation system is configured for separating compounds of the sample fluids and comprises a mobile phase drive configured for driving the mobile phase through a separation unit configured for separating compounds of the sample fluids in the mobile phase. The sample dispatcher comprises one or more sample reservoirs, each configured for receiving and temporarily storing a respective sample fluid portion or at least a part thereof, and a bypass channel.

A sample transfer device, an analytical system for analyzing a sample, a method for sample transfer and a method for manufacturing the sample transfer device are disclosed. The sample transfer device includes at least one first block and at least one second block, wherein the first block has at least one first port and at least one second port, wherein the second block has at least one third port and at least one fourth port. The sample transfer device also has at least one slider. The slider is located between the first block and the second block and is configured to slide from a first position to a second position and vice versa. Both in the first position and in the second position a first straight channel is formed between the first port and the third port and a second straight channel is formed between the second port and the fourth port.

The invention relates to a method which realizes a two-dimensional separation of ionic species on the basis of the online coupling of ion chromatography (IC) and capillary electrophoresis (CE). A device for ICCE coupling, its implementation in terms of two alternatives, the connection to a mass spectrometric detector, and corresponding application are described.

A switching unit is configured for selectively fluidically coupling a sampling volume, a sampling drive, a mobile phase drive, and a separating device. In a sample load configuration, the switching unit is configured for fluidically coupling the sampling volume and the sampling drive, for moving the fluidic sample into the sampling volume. In a decouple configuration, the switching unit is configured for fluidically coupling the sampling volume between the sampling drive and the separating device, while the mobile phase drive is fluidically decoupled from the separating device. In a sample introduction configuration, the switching unit is configured for fluidically coupling the mobile phase drive, the sampling volume, and the separating device for introducing at least an amount of the fluidic sample stored in the sampling volume into the mobile phase for fluid separation by the separating device.

A multi-way valve has an upper part, a lower part and a central part connected to the upper part via an interposing first membrane and the lower part via an interposing second membrane, wherein the upper and lower parts contain recesses on the upper and lower part faces facing the membranes, where a control fluid is introducible into the recesses, the central part contains a pair of openings in regions opposite the recesses on the central part faces lying adjacent to the membranes, where while introducing the control fluid into a recess, the membrane closes respective opposite openings in the central part, and where the membrane otherwise recedes into the recess, thereby releasing the opposite openings, where valve connections are mounted on the upper or lower part such that the central part can have a very thin design while preventing dead regions in the channel systems.

A sample transfer device, an analytical system for analyzing a sample, a method for sample transfer and a method for manufacturing the sample transfer device are disclosed. The sample transfer device includes at least one first block and at least one second block, wherein the first block has at least one first port and at least one second port, wherein the second block has at least one third port and at least one fourth port. The sample transfer device also has at least one slider. The slider is located between the first block and the second block and is configured to slide from a first position to a second position and vice versa. Both in the first position and in the second position a first straight channel is formed between the first port and the third port and a second straight channel is formed between the second port and the fourth port.

A sample dispenser for an analysis device, in particular for an analysis device working according to the principle of liquid chromatography, in particular high pressure liquid chromatography, or gas chromatography, comprising a sample intake for receiving a sample to be analyzed, an inlet through which an eluent can be supplied, an outlet, and an injection valve arrangement, which can be switched at least from an intake position to an injection position, wherein, at least in the intake position and in the injection position, the inlet is in fluid connection with the outlet to deliver the eluentif applicable, having the sample added theretoat least partly to the outlet, wherein, in the intake position, the sample intake is separated from the eluent in a fluid-tight manner, and wherein, in the injection position, the sample in the sample intake can combine with the eluent, wherein the sample dispenser is configured as a disposable component.