Abstract: A switching valve includes a stator and a rotor. The stator includes multiple connection ports. The rotor has predetermined switching positions and interacts with the stator to form a fluidic connection or a fluidic disconnection of predetermined connection ports. The rotor can be mounted rotatably via a bearing and pressing device loaded with a predefined pressing force in a direction of the stator. The bearing and pressing device includes a compensation element to load the rotor and transmit the pressing force. The compensation element is configured to make an elastic flexural deformation so that the compensation element loads the rotor when the rotor is wobbling with respect to an axis of rotation.

Abstract: A mixing device for liquid chromatography for the radial mixing of at least two fluids comprises a tubular mixing line, and a helical flow-guiding element arranged in the mixing line. One or more spacing elements located within an interior region of the mixing line are adapted to maintain a predetermined distance between the outer sides of the helical flow-guiding element and an inner wall of the mixing line. A mixing unit according to the present invention may include such a radial mixing device, with a longitudinal mixing device being connected downstream from this radial mixing device.

Abstract: The invention relates to a flow cell for absorption detection, in which a tube through which flow is to pass is held at its opposite ends in a supporting flange in each case and is suspended in a substantially cantilevered manner, the two supporting flanges being connected rigidly to each other in order to avoid stresses accidentally introduced into the tube.

Abstract: The invention relates to a positioning means for a flow cell used for optical detection, comprising a base having at least one contact face, the contact face being provided to make contact with the end of the flow cell, wherein the base has at least one reference face, which is to be aligned and/or positioned relative to the flow channel of a flow cell, and wherein the base is designed to receive a connecting piece in such a way that the latter assumes a predefined attitude and alignment relative to the flow channel.

Abstract: A method for producing a fluidic connection component for chromatography is described. A connection component includes a main body and at least one insert held in the main body. The main body is prefabricated with an aperture for the at least one insert. The at least one insert is connected to the main body securely and fluidically tightly by a thermal process and by making use of a thermal expansion of the main body and/or of the insert that occurs during the thermal process. The method may include a thermally induced change in volume of the main body and/or of the insert that is retained after completion of the thermal process. The material and the geometry of the main body and of the insert and the thermal process are chosen such that, after completion of the thermal treatment, there is a secure and fluidically tight connection.

Abstract: A sample injector for liquid chromatography includes an injection valve having a waste port, two sample loop ports, and two high-pressure ports. One high-pressure port can be connected to a pump and the other high-pressure port can be connected to a chromatography column. A sample loop is connected to one of the sample loop ports on one end and to a pump volume of a sample conveying device on the other end. A section of the sample loop can be separated to facilitate receiving a sample fluid in the sample loop. A control unit controls the injection valve and the sample conveying device. The sample injector allows a sample to be loaded into the sample loop and then pressurized to an operating pressure prior to injecting the sample into the chromatography column. The sample loop may also be isolated from the operating pressure for facilitating depressurization of the loop.

Abstract: The invention relates to a connector unit for connecting capillaries, in particular for high-performance liquid chromatography, wherein a sealing element sealing the capillary protrudes at least partially into the interior of the capillary, while a portion of the sealing element that protrudes axially from the capillary can be subjected to a compressive force that is introduced via the capillary to obtain an axial or radial plastic and/or elastic deformation.

Abstract: A connector unit for connecting capillaries, in particular for high-performance liquid chromatography is described. A connector capillary projects through a bore of a connector housing. An annular sealing element is provided on a front end region of the connector capillary and which is composed of a plastically and/or elastically deformable material. The connector housing is formed so as to be releasably connectable to a bushing unit. The connector capillary has an inner shell composed of a plastically and/or elastically deformable material and an outer shell which engages around the inner shell and which is composed of a pressure-resistant material. The inner shell has a radially outwardly extending front end region which, on its own or together with the annular sealing element can generate a sealing action between the front end region of the connector capillary and the annular face side of the capillary receiving opening of the bushing unit.

Abstract: The invention relates to a part for a component for high-pressure liquid chromatography (HPLC), in particular a pump head for an HPLC pump, in which the strength has been increased by autofrettage and which consists of a material which is essentially chemically inert to the fluids used in HPLC. The invention further relates to an HPLC pump having a pump head which is configured as such a part.

Abstract: The invention relates to a fluidic plug unit for liquid-conducting components, in particular for high-performance liquid chromatography, with a plug housing that has a plug region with a front plug region and a rear plug region which is adjoined thereto in an axial direction. The rear plug region has a larger cross section than the front plug region. The plug unit is designed for connection to a bushing unit. In a connected state of the plug unit and bushing unit, an annular space, which is substantially closed on all sides, is formed for a sealing element of the plug unit, the annular space being bounded by an outer wall of the front plug region and an inner wall of the receiving recess of the bushing unit.

Abstract: An autosampler for high-performance liquid chromatography (HPLC) with a high-pressure injection valve (1, 2) having improved life, particularly in high pressure operation. The geometry of the valve components and the connections of the high-pressure injection valve are provided such that the switching processes do not take place in a deleterious direction. The grooves in rotor (2) and/or the port opening cross sections (131, 151) in stator (1) and the rotational direction are selected such that fluid flows from grooves under high pressure in the direction of narrow, substantially pressure-free ports are avoided. This applies in particular to the switching process from INJECT to LOAD, since the sample loop contains a relatively large dead volume of compressed fluid. In addition, the valve can be controlled according to the invention in such a manner that an appropriate time is available for reducing harmful or undesired pressure differences.

Abstract: The invention relates to a plug unit 3 for connecting capillary tubes, especially for high-performance liquid chromatography, with a plug capillary tube 10 that projects through a hole of a plug housing 20, wherein the plug housing 20 is constructed so that it can be connected detachably to a bushing unit 5, wherein the front end of the plug capillary tube 10 projects into a capillary tube receptacle opening 53 of the bushing unit 5 when the plug unit 3 and bushing unit 5 are connected, and with its end face essentially aligned opposite a front end of a bushing capillary tube 57 or a bushing capillary tube opening 55 of the bushing unit 5 and the end face of which is butted against, and wherein the plug housing 20 applies a force, with its end face facing the end of the plug capillary tube 10, directly or indirectly on an annular sealing element 40 surrounding the plug capillary tube 10 in the region of the front end of the plug capillary tube 10 when the plug unit 3 and bushing unit 5 are connected such that

Abstract: The invention pertains to a sample injector for liquid chromatography, particularly for high performance liquid chromatography, with a controllable injection valve (3) that features at least one waste port (12) for discharging fluid under low pressure, two sample loop ports (13, 16) and two high-pressure ports (14, 15) for supplying and discharging fluid under high pressure, wherein one high-pressure port (15) can be connected to a pump (40) and the other high-pressure port (14) can be connected to a chromatography column (41), with a sample loop (44, 51, 52) that comprises a first sample loop section (51) that is connected to one of the sample loop ports (16) on one end and to a pump volume (V) of a sample conveying device (5) on the other end, as well as a second sample loop section (44, 52) that is connected to the other sample loop port (13) on one end and to the pump volume (V) of the sample conveying device (5) on the other end.

Abstract: A device for feeding samples to a separating device and for collecting sample fractions generated by means of the separating device, especially for high-performance liquid chromatography, with a first switch valve unit, which has at least eight ports and two switch positions. The device has a dosing device for feeding a sample to the switch valve unit, which is connected to a suction port of the first switch valve unit and which interacts with a removal and discharge device for the removal of a sample from at least one sample-holding container and for the discharge of each fraction into one of several fraction-holding containers, which is connected to a suction and discharge port of the first switch valve unit. The device uses a single switch valve unit configured in a new way to replace the function of two switch valve units, resulting in significantly simpler and cheaper construction.

Abstract: The invention relates to a method for providing a defined fluid flow, especially for use in liquid chromatography. According to the method, a constant total flow (f0) is subdivided into an internal excess flow (fie) in an excess branch and into an internal working flow (fiw) in a working branch. The ratio of subdivision of the internal working flow (fiw) and the internal excess flow (fie) depends on the reverse ratio of a fluidic resistance provided in the working branch and a fluidic resistance in the excess branch. The excess branch and the working branch are interlinked at the respective outputs of the two fluidic outputs of the fluidic resistances by a cross-branch. The equalizing flow occurring between the outputs of the fluidic resistances is measured by means of a flow sensor. A desired, external working flow in the further course of the working branch can be fed to a working device, for example a chromatography column mounted downstream of the device.

Abstract: The invention relates to a method for providing a defined fluid flow, especially for use in liquid chromatography. According to the method, a constant total flow (f0) is subdivided into an internal excess flow (fie) in an excess branch and into an internal working flow (fiw) in a working branch. The ratio of subdivision of the internal working flow (fiw) and the internal excess flow (fie) depends on the reverse ratio of a fluidic resistance provided in the working branch and a fluidic resistance in the excess branch. The excess branch and the working branch are interlinked at the respective outputs of the two fluidic outputs of the fluidic resistances by a cross-branch. The equalizing flow occurring between the outputs of the fluidic resistances is measured by means of a flow sensor. A desired, external working flow in the further course of the working branch can be fed to a working device, for example a chromatography column mounted downstream of the device.