A device for a gas chromatograph (GC) system includes an injector connected to an inlet gas line and a conduit assembly. The inlet gas line is configured to pressurize an input end of a column and to deliver a split or purge flow. The conduit assembly includes a conduit surrounding the input end of the analytical column and coupled to a carrier gas line and a controller. The inlet gas line and the carrier gas line connect to a common gas source. The controller, connected to the conduit, has a first mode delivering a flow of carrier gas which is less than the column flow during an injection period to effect a sample transfer to the column and a second mode delivering a flow of carrier gas greater than the column flow following an injection period to prevent the split or purge flow from entering the column.

A fluid supply system configured for supplying fluids includes a fluid packet supply unit configured for controlling supply of a sequence of fluid packets. The fluid packets include a packet of first fluid and a packet of second fluid, 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 and the packet of second fluid. The fluid supply system further includes a phase separation inhibiting unit configured for inhibiting phase separation by inserting an intermediate fluid packet between the packet of first fluid and the packet of second fluid.

A fluid supply system configured for supplying fluids includes a fluid packet supply unit configured for controlling supply of a sequence of fluid packets. The fluid packets include a packet of first fluid and a packet of second fluid, 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 and the packet of second fluid. The fluid supply system further includes a phase separation inhibiting unit configured for inhibiting phase separation by inserting an intermediate fluid packet between the packet of first fluid and the packet of second fluid.

A cylindrical column body (101) holds a filler. A pair of end caps (105, 106) covers both ends of the column body (101) and has a flow hole for a carrier liquid (111, 112) arranged in the center thereof. An end surface on the side of a large diameter portion (113a, 114a) of a pair of columnar joint members (113, 114) contacts an end surface of the pair of end caps (105, 106) and also has a communication hole (115, 116) arranged in the center thereof. A sealing member (117, 118) is arranged on a contact surface between the end cap (105, 106) and the joint member (113, 114). A bottomed cylindrical case (121) accommodates the pair of end caps (105, 106) and a large diameter portion of the pair of joint members (113, 114) in an engaged state. A cover member (124) is detachably installed on a side of an opening of the case (121).

A cylindrical column body (101) holds a filler. A pair of end caps (105, 106) covers both ends of the column body (101) and has a flow hole for a carrier liquid (111, 112) arranged in the center thereof. An end surface on the side of a large diameter portion (113a, 114a) of a pair of columnar joint members (113, 114) contacts an end surface of the pair of end caps (105, 106) and also has a communication hole (115, 116) arranged in the center thereof. A sealing member (117, 118) is arranged on a contact surface between the end cap (105, 106) and the joint member (113, 114). A bottomed cylindrical case (121) accommodates the pair of end caps (105, 106) and a large diameter portion of the pair of joint members (113, 114) in an engaged state. A cover member (124) is detachably installed on a side of an opening of the case (121).

The measurement of glutaraldehyde-based biocides in seawater without the use of a derivatization agent. The measurement of glutaraldehyde-based biocides in seawater may be performed without additional components to reduce background interferences. The concentration of a glutaraldehyde-based biocides in a seawater sample is determined using reversed phase liquid chromatography and a gradient mobile phase of acetonitrile and deionized water. Systems for determining the concentration of glutaraldehyde-based biocide in a seawater injection system are also provided.

The measurement of glutaraldehyde-based biocides in seawater without the use of a derivatization agent. The measurement of glutaraldehyde-based biocides in seawater may be performed without additional components to reduce background interferences. The concentration of a glutaraldehyde-based biocides in a seawater sample is determined using reversed phase liquid chromatography and a gradient mobile phase of acetonitrile and deionized water. Systems for determining the concentration of glutaraldehyde-based biocide in a seawater injection system are also provided.

An online HPLC dissolution test system includes a dissolution tester and a liquid chromatograph. An autosampler of the liquid chromatograph includes at least one flow vial, a sampling needle and an injection port. The flow vial is connected to the dissolution tester via a pipe and is for storing a sample solution supplied from the dissolution tester therein. The sampling needle is for collecting the sample solution by sucking from the flow vial. The injection port is for injecting the sample solution from the sampling needle into the analysis channel. The controller of the liquid chromatograph includes an immediate analyzing execution part configured to cause the autosampler to execute immediate analyzing operation for sucking the sample solution in the flow vial with the sampling needle and directly injecting the sample solution into the injection port when the sample solution is supplied from the dissolution tester to the flow vial.

A sample injector for injecting a fluid into a fluidic path, wherein the sample injector comprises a robot arm configured for moving an injection needle, when being connected to the robot arm, between a fluid container containing the fluid and a seat in fluid communication with the fluidic path, the needle configured for aspirating the fluid from the fluid container, when the needle has been moved to the fluid container, and for injecting aspirated fluid into the fluidic path, when the needle is accommodated in the seat, and the seat configured for accommodating the needle and providing fluid communication with the fluidic path, wherein the robot arm is configured for selectively disconnecting the needle from the robot arm when the needle is accommodated in the seat, and wherein the robot arm is configured for performing a further task while the needle is disconnected from the robot arm.

A sample injector for injecting a fluid into a fluidic path, wherein the sample injector comprises a robot arm configured for moving an injection needle, when being connected to the robot arm, between a fluid container containing the fluid and a seat in fluid communication with the fluidic path, the needle configured for aspirating the fluid from the fluid container, when the needle has been moved to the fluid container, and for injecting aspirated fluid into the fluidic path, when the needle is accommodated in the seat, and the seat configured for accommodating the needle and providing fluid communication with the fluidic path, wherein the robot arm is configured for selectively disconnecting the needle from the robot arm when the needle is accommodated in the seat, and wherein the robot arm is configured for performing a further task while the needle is disconnected from the robot arm.