A gas chromatograph with column recognition technology system for the column includes a column and the column recognition technology system for the column. The column is configured for gas chromatography. The column includes column parameters associated with the column. The column recognition technology system may be configured to auto-recognize the column in the gas chromatograph device. Wherein, the column recognition technology system may be configured to auto-recognize the column parameters associated with the auto-recognized column.

An opening sealing structure is provided with a housing, a step portion, a seal cap, an elastic sealing member, and a cap fixture. The housing has a cap mounting portion having a a cylindrical shape. The step portion is provided on the outer peripheral surface of the cap mounting portion and has a side surface facing the base end side of the cap mounting portion. The side surface of the step portion is inclined along the circumferential direction of the cap mounting portion from the tip end side of the cap mounting portion to the base end side and its inclination angle is smaller on the base end side of the cap mounting portion than on the tip end side. The cap fixture has a cap holding portion movably engaged with the seal cap in a circumferential direction of its outer peripheral surface and an elastic portion connected to the cap holding portion. The elastic portion is provided with a protrusion which engages the side surface of the step portion.

Disclosed is a separation column for micro gas chromatography, having superior separation performance and including a microchannel formed on a substrate and having a serpentine shape, and bumps formed on the surface of the microchannel, wherein the bumps are alternately disposed to face each other on the surface of the microchannel. In the separation column for micro gas chromatography, a sufficient pressure drop occurs, and thus an M interaction between a gas mixture to be analyzed and a stationary phase in the column sufficiently takes place, whereby individual gas components are efficiently separated from the gas mixture, discharged from the column, and detected.

The auto-sampler for chromatographs includes a needle for sampling configured to move while a tip end thereof faces vertically downward; a switching valve having a plurality of ports to which channels constituting a chromatograph are connected, the switching valve switching between port connecting conditions to switch between channel configurations; and an injection port including an opening at an upper surface thereof through which a tip end of the needle is inserted to make the needle fluidically communicate with a pipe connected to one port of the switching valve, and a needle seal configured to get into contact with an outer circumferential surface of the tip end portion to make the needle fluidically communicate with the pipe in a liquid-tight manner when the tip end of the needle is inserted through the opening.

A disposable chromatography sample introduction device includes a stylus with a holder and a tubular stem extending from one end of the holder containing porous sample-holding material. The stylus has a pair of spaced openings permitting fluid flow therethrough. An injector housing includes an insertion port for receiving the stylus, a seal, an inlet port for communicating with one stylus opening, and an outlet port for communicating with the other stylus opening. When the stem is immersed in a sample, sample enters the stem by capillary action. Thereafter, the stylus is inserted into the housing insertion port where mobile phase flowing from inlet port to outlet port passes through the stem extracting sample. The holder has a finger grip and an external thread that engages a complementary injector housing thread to secure the holder when the stylus is inserted therein.

A needle receiving assembly includes a fluid conducting element housing, a sealing element configured to receive a needle, and a fluid conducting element. The needle receiving assembly is configured to connect to a needle of a needle assembly. The fluid conducting element housing comprises an aligning component configured to contact a needle housing of the needle assembly and to increase alignment between the needle and the needle receiving assembly. The fluid conducting element housing comprises a lateral protruding portion including an inner lateral surface that laterally surrounds a cavity of the fluid conducting element housing and a central protruding portion protruding beyond a base of the fluid conducting element housing and the central protruding portion. The aligning component comprises an aligning inner surface formed by a portion of the inner lateral surface of the lateral protruding portion.

A ferrule includes a deformable portion and a rigid sleeve surrounding at least a portion of the deformable portion. The deformable portion includes between about 5% and about 50% graphite. The deformable portion further includes between about 50% and about 95% polyimide. The rigid sleeve can include a metal, such as stainless steel.

The present invention relates to a needle assembly comprising a needle, a needle housing, wherein the needle housing comprises at least one aligning component. The present invention also relates to a needle receiving assembly comprising a fluid conducting element and a fluid conducting element housing, wherein the fluid conducting element housing comprises at least one aligning component. Additionally, the present invention relates to connection assemblies, samplers and systems that can comprise the needle assembly and the needle receiving assembly.

An autosampler comprises a needle unit having a needle holding part that holds a needle for aspirating and discharging fluid through a tip thereof, the needle unit moving the needle holding part in a vertical direction while moving in a horizontal direction; an injection port having therein a flow path to which the needle is fluidly connected during sample injection, wherein an opening communicating with the flow path is provided on an upper surface, a seal part is provided inside the opening, against which an outer peripheral surface of the tip of the needle is pressed when the needle descends to a predetermined height from above the opening, and the tip of the needle being pressed against the seal part causes the needle to be fluidly connected in a liquid-tight manner to the flow path; and a magnetic force part provided to apply a magnetic force in a direction that pushes down the needle holding part, at least in a state where the outer peripheral surface of the needle is pressed against the seal part in the injection port.