Abstract: Disclosed is a pumping apparatus (200) configured for delivering a fluid. The pumping apparatus (200) comprises a pumping chamber (220) configured for receiving one or more fluids (310, 320) in defined proportions and for further delivering the received fluids, an outlet (240), fluidically coupling to a first position (350) in the pumping chamber (220), for outleting the fluid to be delivered, and a channel (410). The channel (410) fluidically couples on one side to a second position (340) in the pumping chamber (220) and on the other side to the outlet (240), so that—in operation—a first portion of the delivered fluid as outlet at the outlet (240) is received from the first position (350) in the pumping chamber (220), and a second portion of the delivered fluid as outlet at the outlet (240) is received from the second position (340) in the pumping chamber (220).

Abstract: Disclosed is a sample dispatcher configured for individually introducing a plurality of portions of one or more sample fluids into a flow of a mobile phase of a separation system configured for separating compounds of the sample fluids. The separation system 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 a plurality of sample reservoirs, each configured for receiving and temporarily storing a respective sample fluid portion or at least a part thereof. The sample dispatcher is configured for selectively coupling one of the plurality of sample reservoirs between the mobile phase drive and the separation unit, and further for coupling at least two of the plurality of sample reservoirs in parallel between the mobile phase drive and the separation unit.

Abstract: A multi-dimensional liquid analysis system includes a flow splitter for separating mobile phase outflow from a first dimension liquid analysis system into fist and second liquid split outlet flows. Volumetric flow rate control of the split outlet flows is provided by a flow control pump which withdraws one of the split outlet flows from the flow splitter at a controlled withdrawal flow rate to define the other split outlet flow rate as the difference between the outflow rate from the first dimension system and the withdrawal flow rate. In this manner, accurate and consistent flow division can be accomplished, which is particularly useful for multi-dimensional liquid analysis.

Abstract: A sample separation apparatus includes a fluidic valve including a first inlet fluidically coupled to one of a first fluid drive and a second fluid drive, and a second inlet fluidically coupled to the other of the first fluid drive and the second fluid drive. The fluidic valve includes at least two different sets of storage paths, wherein each set of storage paths comprises a first storage path. The first storage path of a first set of said at least two sets of storage paths has a first volume, and the first storage path of a second set of said at least two sets of storage paths has a second volume different from the first volume. The fluidic valve is configured for selectively switching one set of the least two sets of storage paths to the first inlet and the second inlet.

Abstract: A multi-dimensional liquid analysis system includes a flow splitter for separating mobile phase outflow from a first dimension liquid analysis system into first and second liquid split outlet flows. Volumetric flow rate control of the split outlet flows is provided by a flow control pump which withdraws one of the split outlet flows from the flow splitter at a controlled withdrawal flow rate to define the other split outlet flow rate as the difference between the outflow rate from the first dimension system and the withdrawal flow rate. In this manner, accurate and consistent flow division can be accomplished, which is particularly useful for multi-dimensional liquid analysis.

Abstract: A device for determining a leakage of fluid in a piston pump, wherein the piston pump comprises a piston arranged in such a manner that it can reciprocate in a piston chamber for delivering fluid, wherein the device comprises a control unit for controlling the piston in such a manner that the piston executes two piston chamber evacuation processes with different evacuation times, in each case for at least partial evacuating of fluid located in the piston chamber, and a determination unit for determining the leakage based on a comparison of fluid quantities evacuated from the piston chamber in the two piston chamber evacuation processes.

Abstract: A sample separation apparatus (100, 200) for separating a fluidic sample (104), the sample separation apparatus (100, 200) comprising: a first separation unit (102) for separating the fluidic sample (104); a first fluid drive (106) configured for generating a fluid flow for conducting the fluidic sample (104) to be separated through the first separation unit (102); a second separation unit (110), arranged downstream of the first separation unit (102), for further separating the fluidic sample (104) after treatment by the first separation unit (102); a second fluid drive (112) configured for generating a fluid flow for conducting the fluidic sample (104) or at least parts thereof, after treatment by the first separation unit (102), through the second separation unit (110); a fluidic valve (114) having a first inlet (116) fluidically coupled to one of the first fluid drive (106) and the second fluid drive (112); the fluidic valve (114) having a second inlet (118) fluidically coupled to the other of the first fl

Abstract: A voltage control circuitry for a detection cell is described, where the detection cell is adapted for determining an electrical property of a sample in a detection cell volume of the detection cell. The voltage control circuitry comprises a power supply adapted for providing a voltage to the detection cell, and a power evaluation unit adapted for determining an actual power dissipation in the detection cell volume. The voltage control circuitry further comprises a control unit adapted for comparing the actual power dissipation with a desired power dissipation, and for regulating the power supply's voltage in a way that the actual power dissipation is driven towards the desired power dissipation.

Abstract: A sample separation apparatus (200) for separating a fluidic sample, the sample separation apparatus (200) comprising a first separation unit (204) for separating the fluidic sample, a first fluid drive (202) configured for conducting the fluidic sample to be separated through the first separation unit (204), a second separation unit (208), arranged downstream of the first separation unit (204), for further separating the fluidic sample after treatment by the first separation unit (204), a second fluid drive (206) configured for at least partially conducting the fluidic sample, after treatment by the first separation unit (204), through the second separation unit (208), and a fluidic valve (218) having fluidic interfaces (222, 224, 226, 228) fluidically coupled to the first fluid drive (202) and the second fluid drive (206) and being switchable for performing the separation of the fluidic sample, wherein the sample separation apparatus (200) is configured for adjusting a pressure at a predefined position to a

Abstract: A fluid supply system (150) configured for supplying fluids, the fluid supply system (150) comprising a fluid packet supply unit (180) configured for controlling supply of a sequence (250) of fluid packets (222 to 230), the fluid packets (222 to 230) comprising a packet of first fluid (223) and a packet of second fluid (225), wherein the first fluid and the second fluid are media being prone to a phase separation upon direct interaction between the packet of first fluid (223) and the packet of second fluid (225), and a phase separation inhibiting unit (190) configured for inhibiting phase separation by inserting an intermediate fluid packet (224) between the packet of first fluid (223) and the packet of second fluid (225) to 230 to 230

Abstract: 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.

Abstract: A filter for filtering debris out of a fluid flowing along a fluid flow direction in a fluidic member of a sample separation device, the filter comprising a plurality of filter structures stacked along the fluid flow direction and each having pores with defined pore size, wherein the defined pore size of the stacked filter structures decreases along the fluid flow direction.

Abstract: A fluid supply system (150) adapted for metering two or more fluids in controlled proportions and for supplying a resultant mixture, the fluid supply system (150) comprising a plurality of solvent supply lines (104 to 107), each fluidically connected with a fluid source (100 to 103) providing a respective fluid, a pumping unit (110) comprising a reciprocating element (115) adapted for intaking fluid supplied at an inlet of the pumping unit (110) and for supplying the pressurized fluid at an outlet of the pumping unit (110), wherein the pumping unit (110) is adapted for taking in fluids from selected solvent supply lines (104 to 107) and for supplying a pressurized mixture of the fluids at its outlet, a proportioning valve (108) interposed between the solvent supply lines (104 to 107) and the inlet of the pumping unit (110), the proportioning valve (108) adapted for modulating solvent composition by sequentially coupling selected ones of the solvent supply lines (104 to 107) with the inlet of the pumping unit

Abstract: A control device for a sample separation apparatus, the sample separation apparatus including a first separation unit and a second separation unit downstream of the first separation unit and supplied with the fluidic sample after treatment by the first separation unit. A control device is configured for controlling the first separation unit to execute a primary separation sequence within a time interval for separating the fluidic sample into fractions, and for controlling the second separation unit to execute secondary separation sequences within the time interval for further separating the separated fractions into sub-fractions, wherein the secondary separation sequences form part of a common sample separation method defined by a common specification of the sample separation involving a set of parameters, and adjusting, over a progress of the primary separation sequence, at least one parameter according to which at least one of the plurality of secondary separation sequences is executed.

Abstract: A control device for a sample separation apparatus, the sample separation apparatus including a first separation unit and a second separation unit downstream of the first separation unit and supplied with the fluidic sample after treatment by the first separation unit. A control device is configured for controlling the first separation unit to execute a primary separation sequence within a time interval for separating the fluidic sample into fractions, and for controlling the second separation unit to execute secondary separation sequences within the time interval for further separating the separated fractions into sub-fractions, wherein the secondary separation sequences form part of a common sample separation method defined by a common specification of the sample separation involving a set of parameters, and adjusting, over a progress of the primary separation sequence, at least one parameter according to which at least one of the plurality of secondary separation sequences is executed.

Abstract: A voltage control circuitry for a detection cell (1) is described, whereby the detection cell (1) is adapted for determining an electrical property of a sample in a detection cell volume (2) of the detection cell (1). The voltage control circuitry comprises a power supply (5) adapted for providing a voltage (6) to the detection cell (1), and a power evaluation unit adapted for determining an actual power dissipation in the detection cell volume (12). The voltage control circuitry further comprises a control unit (14) adapted for comparing the actual power dissipation with a desired power dissipation, and for regulating the power supply's voltage (6) in a way that the actual power dissipation is driven towards the desired power dissipation.

Abstract: A mixer for mixing a fluid having a property varying along a flow direction of the fluid includes an inlet configured for receiving an inlet flow, an outlet configured for providing an outlet flow, and a plurality of flow channels coupled between the inlet and the outlet. The mixer also includes a flow distributor for distributing the inlet flow into the plurality of flow channels so that each flow channel receives a partial flow from the inlet flow, and a flow combiner for combining the partial flows from the plurality of flow channels to the outlet flow. Each flow channel has a first flow section having a hydraulic resistance substantially representing a hydraulic resistance of the flow channel. One or more of the flow channels each have a second flow section coupled in series with the first flow section of the respective flow channel.

Abstract: An apparatus for determining an operation mode of a device, wherein the device is capable of adjusting a physical condition at a source position to correspondingly influence a physical condition at a destination position, the apparatus comprising a determining unit adapted for determining the operation mode by defining a time dependency of the physical condition at the source position so that a target time-dependency of the physical condition is obtained for the destination position, the target time-dependency representing a resultant variation of the physical condition over time.

Abstract: A two-dimensional liquid chromatography in a system (200) comprises a first liquid chromatograph (210) coupled with a second liquid chromatograph (220). An injection event of injecting an output of the first liquid chromatograph (210) into the second liquid chromatograph (220) is controlled (290) in relation to a state (600, 610; 620, 630) of the second liquid chromatograph (220). FIG.

Abstract: A fluid supply system configured for metering two or more fluids in controlled proportions, including a plurality of solvent supply lines, a pumping unit configured for taking in fluids from selected solvent supply lines and for supplying a pressurized mixture, a proportioning valve configured for modulating solvent composition by sequentially coupling selected ones of the solvent supply lines with the inlet of the pumping unit, a sensor configured for sensing process information in the fluid supply system, an analysis entity configured for analyzing the process information for determining reciprocating element related information at a beginning of fluid intake, and a control unit configured for switching the proportioning valve to sequentially couple selected ones of the solvent supply lines to the inlet of the pumping unit at one or more switching points based on the given metering scheme and based on the reciprocating element related information.