A method of preparing a liquid mixture for use in a liquid chromatography system is provided. The mixture comprises one or more acids, one or more bases, one or more solvents and water, and the method comprises the steps of: calculating pH and/or solvent concentration at a particular time t from a user-determined gradient function; and, based on the values obtained, calculating percent acid, percent base, percent solvent and percent water in the liquid mixture at time t. A liquid chromatography system incorporating such method is also provided.

Described is a mixer for a liquid chromatography system. The mixer includes a flow distributor, a mixing disk and a flow collector. The mixer includes an inlet face, an outlet face and a plurality of channels each having an inlet end at the inlet face and an outlet end at the outlet face. The channels have a flow direction anisotropy between the inlet and outlet faces. A compositional solvent stream received at the flow distributor is distributed across the inlet face of the mixing disk and the flow collector collects the distributed solvent composition stream after passing through the mixing disk. The mixing disk may include a dispersive medium having a random porous structure. A retention time distribution of the mixer may depend on the structure of the channels between the inlet and outlet faces of the mixing disk.

A mixer arrangement for use in a chromatography system includes a first frequency targeting mixer including a first flow channel coupled between an inlet and an outlet and a second flow channel coupled between the inlet and the outlet, the second flow channel including a volume offset region configured to delay fluid propagation through the second flow channel, wherein the volume offset region is configured to reduce or eliminate fluidic compositional oscillations in a compositional solvent stream that depart from a desired composition at a first target frequency, and a residual noise targeting mixer fluidically connected in series to the frequency targeting mixer, the residual noise targeting mixer configured to dampen aperiodic baseline noise in the compositional solvent stream.

The present invention relates to a system for analysing the composition of a quenched flow reaction liquid comprising a quenched flow reactor, and a high performance liquid chromatography (HPLC) apparatus; wherein the quenched flow reactor is in fluid communication with the HPLC apparatus.

A mixer for mixing a mobile phase in a sample separation device for separating a fluidic sample, wherein the mixer includes a fluid inlet for supplying the mobile phase to be mixed to a mixing volume, a movable body configured for rotating and axially moving in the mixing volume to thereby mix the mobile phase, and a fluid outlet for supplying the mixed mobile phase to a mobile phase consumer.

The liquid delivery device includes a liquid delivery controller configured to operate, in a complementary manner, a primary plunger pump and a secondary plunger pump of each of a first liquid delivery pump and a second liquid delivery pump so that the first liquid delivery pump and the second liquid delivery pump perform continuous liquid delivery at a preset flow rate to each other, and a forcible synchronization part configured to forcibly synchronize operation states of the secondary plunger pumps of the first liquid delivery pump and the second liquid delivery pump by operating the primary plunger pump and the secondary plunger pump of the first liquid delivery pump and the second liquid delivery pump at the calculated operation speed.

A system for preparing solutions for chromatography application is disclosed. The system comprises a T-joint for preparing a buffer solution by mixing at least one first solution and a second solution. The T-joint receives the second solution from a solution supply unit connected to the T-joint. Further one or more low pressure pumps supply the one or more first solutions into the T-joint. The high pressure pump collects the buffer solution and delivers it to a chromatography apparatus.

Disclosed is a gradient proportioning valve for liquid chromatography that includes a plurality of inlet ports configured to receive a plurality of fluids, a manifold connected to each of the plurality of inlet ports configured to mix the plurality of fluids in a controlled manner to provide a fluid composition, the manifold including a plurality of fluid conduits internal to the manifold, each of the plurality of fluid conduits receiving fluid through a respective one of the plurality of inlet ports, each of the plurality of fluid conduits operatively communicable to a respective actuation mechanism configured to open and close each of the plurality of fluid conduits in a controlled manner, a common outlet port configured to receive the fluid composition, and a passive fluidic dampening system configured to dampen unwanted fluidic pressure pulses in the manifold where at least one of the plurality of fluid conduits is compliant.

A continuous flow mixer for use in a chromatography system includes a first channel structure located between a mixer inlet and a mixer outlet. The first channel structure includes a first inlet branch, a second inlet branch, a plurality of outlet branches including at least a first outlet branch and a second outlet branch, a first plurality of branches splitting from the first inlet branch, each branch of the first plurality of branches connected to a different of the plurality of outlet branches, and a second plurality of branches splitting from the second inlet branch, each branch of the second plurality of branches connected to a different of the plurality of outlet branches. At least two branches of the first and second plurality of branches that are connected to the first outlet branch are offset in fluid residence time through the at least two branches.

Disclosed is a gradient proportioning valve for use in liquid chromatography that includes a plurality of inlet ports configured to receive a plurality of fluids, a manifold connected to each of the plurality of inlet ports configured to mix the plurality of fluids in a controlled manner to provide a fluid composition, the manifold including a plurality of conduits internal to the manifold, each of the plurality of conduits receiving fluid through a respective one of the plurality of inlet ports, each of the plurality of conduits operatively communicable to a respective actuation mechanism configured to open and close each of the plurality of conduits in a controlled manner, a common outlet port configured to receive the fluid composition, and an active fluidic dampening system configured to dampen unwanted fluidic pressure pulses in the manifold. Liquid chromatography systems and methods are further disclosed.