DE102024102760A1 - Sliding element for an analysis device - Google Patents

Abstract

A sliding element (150) for an analysis device (10) is described, wherein the analysis device (10) is designed in particular as a sample separation device for separating a fluid sample in a sample separation device (30), in particular a chromatographic separation column, and has the sliding element (150). : a coupling area for coupling the sample separation device (30). The sliding element (150) is designed to bring the coupled sample separation device (30) into a position with respect to the analysis device (10), in particular with respect to a temperature control chamber (160) of the analysis device (10), when it is moved.

Description

TECHNICAL BACKGROUND

The present invention relates to a sliding element for an analysis device (e.g. a chromatography device) for analyzing a fluidic sample, the sliding element having a coupling region for coupling a sample separation device (e.g. a chromatographic column). The sliding element is set up to bring the sample separation device into a position relative to the analysis device when moving, for example a sample separation position. The invention further relates to a sliding element arrangement and a method for bringing a sample separation device into a specific position in an analysis device.

Analysis devices are, for example, chromatography devices, in particular sample separation devices, for analyzing a sample, in particular fluidic sample, for example for carrying out a chromatographic separation of the sample.

For example, in a high performance liquid chromatography (HPLC) chromatography machine, a liquid (mobile phase) is flowed at a very precisely controlled flow rate (e.g. in the range of microliters to milliliters per minute) and at a high pressure (typically 20 to 1000 bar and beyond, currently up to 2000 bar), at which the compressibility of the liquid can be noticeable, moved through a so-called stationary phase (for example in a chromatographic column) to separate individual fractions of a sample liquid introduced into the mobile phase separate. After passing through the stationary phase, the separated fractions of the fluidic sample are detected in a detector. Such an HPLC system is known, for example, from EP 0,309,596 B1 same applicant, Agilent Technologies, Inc.

The actual sample separation of the fluidic sample (in the mobile phase) takes place in a sample separation device that contains the stationary phase. Such a sample separation device is usually implemented as a chromatographic column, which is arranged in a temperature control chamber or a column oven. Due to the arrangement inside the temperature control chamber, the sample separation device can be tempered; in particular, heat exchangers are provided in the temperature control chamber for this purpose. Conventionally, a sample separation device is attached inside the temperature chamber, for example with rubber clips.

Furthermore, fluid temperature control devices are often used to temper a fluid (in particular the mobile phase; with or without fluidic sample) before the fluid is flowed through the sample separation device. Such a fluid temperature control device is fluidly connected to the inlet of the sample separation device (an additional fastening step is necessary for this). In addition, the fluid temperature control device is arranged on a heat exchanger (e.g. in a groove with a triangular cross section).

In practice, however, it has now been shown that such fastening and connecting of a sample separation device in an analysis device can be complex and laborious and, in normal cases, an operator's two hands are not sufficient for this. There may also be some conventional disadvantages with regard to flexibility in operation, e.g. limited column length, limited number of columns for space reasons, unreliable allocation of the columns in the column oven, etc.

SUMMARY OF THE INVENTION

There may be a need to locate or connect a sample separation device in an analysis device in an efficient and reliable manner.

A sliding element, a sliding element arrangement, an analysis device, a method for bringing a sample separation device into a certain position, and use are described below.

According to a first aspect of the invention, a sliding element (e.g. a slider) is described for an analysis device (the analysis device being set up in particular as a sample separation device for separating a fluidic sample in a sample separation device, in particular a chromatographic separation column), the sliding element having: a coupling area (e.g. a (planar) main surface for coupling the sample separation device (e.g. via a connection element, in particular with a pivoting mechanism). The sliding element is set up, when moving the sample separation device into a (certain) position with respect to the analysis device (in particular with respect to a Temperature control chamber of the analysis device) (e.g. to carry out sample separation within the analysis device).

According to a second aspect of the invention, a sliding element arrangement for an analysis device is described, the arrangement comprising: a sliding element (as described above) and a) the sample separation device, which is connected to the Coupling area of the sliding element is coupled, and / or b) a fluid temperature control device, which is coupled to the further coupling area of the sliding element.

According to a third aspect of the invention, an analysis device for analyzing a fluidic sample, in particular to be injected into a mobile phase, is described, the analysis device having: a sliding element (as described above) and / or a sliding element arrangement (as described above), wherein the Sliding element and / or the sliding element arrangement is displaceable in relation to the analysis device.

According to a fourth aspect of the invention, a method is described for bringing a sample separation device into a specific position in an analysis device, the method comprising:

i) coupling the sample separation device (in particular a chromatographic separation column) to a sliding element (e.g. as described above); and

ii) moving the sample separation device by means of the sliding element in relation to the analysis device to the specific position (e.g. in the column oven).

According to a fifth aspect of the invention, using a sliding element and/or a sliding element arrangement (see above) for introducing and/or expelling a sample separation device with respect to a temperature chamber of an analysis device (in particular in a horizontal or vertical direction) is described.

In the context of this document, the term “fluidic sample” is understood to mean in particular a medium, more particularly a liquid, which contains the matter actually to be analyzed (for example a biological sample), such as a protein solution, a pharmaceutical sample , Etc.

In the context of the present document, the term “mobile phase” is understood to mean in particular a fluid, more particularly a liquid, which serves as a carrier medium for transporting the fluidic sample between a fluid drive and a sample separation device. However, mobile phase can also be used in a fluid delivery device to influence the fluidic sample. For example, the mobile phase may be a solvent (e.g., organic and/or inorganic) or a solvent composition (e.g., water and ethanol).

In the context of the present document, the term “analysis device” can in particular refer to a device that is able and configured to examine a fluidic sample, in particular to separate it, and further in particular to separate it into different fractions. For example, such sample separation can be carried out using chromatography or electrophoresis. Preferably, the analysis device can be a liquid chromatography sample separation device. The analysis device is in particular configured to carry out an analysis method or a (possibly planned or programmed) sequence of analysis methods or procedures. Furthermore, the term “analysis method” can also be used to represent a sequence, a sequence, a program, an execution list of analysis methods, procedures or regulations, including adjustment, preparation, equilibration (intermediate) steps, etc.

In the context of the present document, the term “pushing element” can in particular refer to a device which is suitable for coupling at least one further element and then displacing it (pushing can also include pushing, pulling, or placing). In an illustrative example, the sliding element can be designed as a carriage. In a simple example, the sliding element can have a body with a main surface to which the further element is coupled, for example placed. The sliding element can, for example, have two main extension directions and thereby provide two opposing main surfaces. In a more complex example, the sliding element can have special coupling structures, e.g. a connecting element (with a pivoting mechanism) for connecting (in particular screwing on) a sample separation device. Furthermore, the sliding element can also be set up to provide a fluidic coupling to the sample separation device. At least a part of the sample separation device can be placed on (the main surface of) the sliding element (or supported by it). The sliding element can also have a second coupling area in order to couple another element, for example a fluid temperature control device. In further examples, the sliding element can have a variety of advantageous functionalities, e.g. a holding element, a pressing element, a guide element, a handling element, etc. In a preferred example, the sliding element can be pushed in and out of a temperature control chamber of an analysis device, with at least one of the sample separation device and fluid temperature control device is coupled to the sliding element (in particular fluidly connected to it).

In the context of the present document, the term “coupling area” can in particular refer to a part of the sliding element which is suitable for coupling, in particular for fastening, an element associated with the analysis device (e.g. the sample separation device). Such a coupling area can, for example, have a holding element (e.g. a ring for clicking in) or a connecting element (e.g. for screwing on). Furthermore, a coupling area can also serve as a shelf (for example of the sample separation device) or as a contact surface (for example of the fluid temperature control device using pressure elements).

In the context of the present document, the term “position” can in particular designate a location (or a locality) to which the sliding element is intended to push the sample separation device and/or the fluid temperature control device. In a preferred example, the sample separation device/fluid temperature control device is inserted into a temperature-controlled area of the analysis device (a temperature control chamber, in particular a column oven), so that the desired position can also be located in this area. In one example, the desired position is located in particular where the separation of the fluidic sample will also be carried out. For example, a second fluidic connector (which leads to the detector) is arranged in the temperature control chamber, to which an output of the sample separation device is connected. This connection position would then be the desired position, for example. If several sample separation devices are arranged (next to one another) in the temperature control chamber, the desired position can also refer to the area where a specific sample separation device is to be arranged (in relation to the other sample separation devices).

According to an exemplary embodiment, the invention can be based on the idea that a sample separation device can be arranged or connected in an analysis device in an efficient and reliable manner if the sample separation device is coupled to a sliding element, by means of which the sample separation device can then be moved directly to the desired position within a temperature control chamber of the analysis device is pushed.

A variety of advantages can be achieved using the sliding element. First, the sample separation device can be coupled to the sliding element and precisely moved to the connection position in the analysis device. Guide structures (particularly rails) can ensure that only the desired displacement path is possible. In one example, the sample separation device can already be fluidly connected (with the input) to the sliding element, so that connection (of the output) is only carried out within the analysis device. For example, an advantageous swivel mechanism (see below) can be used for connection. The sliding element can be set up to be used with a variety of different lengths of the sample separation device. Accordingly, in one example, there is no need to adapt the length of the sample separation device. For example, a fluid connector (e.g. a capillary) of the sliding element can always have the same length in order to fluidly connect the sample separation device, so that a large number of different sample separation device lengths are possible.

In a preferred example, a fluid temperature control device (which pre-temperatures the fluid before it flows into the sample separation device) can also be coupled to the sliding element, so that the sample separation device and fluid temperature control device are pushed together (and already fluidically coupled) into the analysis device can.

Thanks to the predetermined position on the sliding element, tag functionality can also be implemented very efficiently. It can also be possible to insert the sample separation device in a horizontal direction away from the operator/device operator/operator or in a vertical direction into a temperature control chamber (in particular, the sample separation device is held in a vertical orientation against gravity).

In one example, the sliding element makes it possible to install chromatographic columns of different lengths in the column oven without the flow path lengths at the sensitive transitions from fluid temperature control device to sample separation device and sample separation device to detector having to vary or be kept artificially long (e.g. through twisted capillary pieces). Particularly when fluid quick connectors (e.g. the swivel mechanism described below) are used, the entire installation process of the sample separation device can be carried out in one-handed operation. Furthermore, the sliding element described can be implemented directly into existing analysis devices due to its flexible usability.

EXEMPLARY EMBODIMENTS

Additional preferred embodiments are described below.

According to one embodiment, the sliding element has: a second coupling beam rich for coupling a fluid temperature control device for pre-tempering a fluid upstream of the sample separation device. According to an exemplary embodiment, the sliding element is set up to bring the sample separation device and the fluid temperature control device together into a position with respect to the analysis device, in particular with respect to the temperature control chamber of the analysis device, when moving. This can result in the particular advantage that the sample separation device and fluid temperature control device can both be pre-assembled on the sliding element and can then be pushed in or out together. Advantageously, the sample separation device and fluid temperature control device can already be fluidly coupled to one another on the sliding element. Accordingly, complicated connection of these components within the temperature control device can be eliminated.

In this context, the term “fluid temperature control device” can in particular refer to a device which is suitable for pre-heating a fluid (e.g. a mobile phase; with or without fluidic sample). In one example, the fluid temperature control device can be provided elongated, in particular column-shaped, in order to realize a temperature control path. The temperature change can be provided within the temperature control chamber, for example by means of a heat exchanger. Preferably, an input of the fluid temperature control device can be connected to the input of the sample separation domain, while an output of the fluid temperature control device is coupled to the input of the sample separation device.

According to an exemplary embodiment, the first coupling region has a first main surface, which is set up for coupling the sample separation device. According to one exemplary embodiment, the second coupling region has a second main surface, which is set up for coupling the fluid temperature control device. According to one embodiment, the first main surface is arranged opposite the second main surface. The main surfaces of the sliding element can be referred to, for example, as the top and bottom. In one example, the sliding element is essentially planar, so that two opposing main surfaces are provided. This can have the advantage that the sample separation device and fluid temperature control device can be arranged opposite each other (with the sliding element in between), and can therefore be moved together in a space-saving and stable manner.

According to one exemplary embodiment, the sliding element is set up so that the sample separation device and the fluid temperature control device can be fluidly coupled to one another, in particular so that the fluid temperature control device is arranged in a flow path upstream of the sample separation device. According to an exemplary embodiment, the sliding element further has: at least one connection element on the coupling region for, in particular, soluble (fluidic and/or mechanical) connection of the sample separation device. This can have the advantage that the sample separation device and fluid temperature control device are coupled directly to the sliding element (in particular fluidically; i.e. a fluid can flow from the fluid temperature control device into the sample separation device). The sample separation device can be connected efficiently using the connection element.

According to one exemplary embodiment, the sliding element has: a separation path input connection or fluid connector (which can be designed as a fluid path (e.g. channel, capillary, conduit, fluid line)), which realizes the fluidic connection between the sample separation device and the fluid temperature control device. The connection element and the fluid connector (separation path input connection fluid path) can be provided as separate structures (see e.g 2 ), or be installed together. In one embodiment, the fluid connector can extend (at least partially) through the connection element (see also, for example 2 ). In a preferred example, the fluid connector (in particular as a capillary) is provided as short as possible. By mounting on the sliding element, a defined length can be provided for the fluid connector, regardless of the column length (since only the column inlet is fluidly connected to the sliding element).

According to one exemplary embodiment, the connection element has: a pivoting mechanism for fluidly and/or mechanically coupling the sample separation device to the sliding element. According to one embodiment, the sliding element has a first fluidic connector, set up for fluidic coupling to a first fluidic interface of the sample separation device. According to one exemplary embodiment, the sliding element is set up to fluidly couple a second fluidic interface of the sample separation device to a second fluidic connector of the temperature control device. According to one embodiment, the pivoting mechanism is set up to pivot the first fluidic connector between a coupling orientation for coupling the first fluidic interface to the first fluidic connector and an alignment orientation for aligning the sample separation device. According to one embodiment, the pivoting mechanism has a hinge element ment on. Alternatively, reversible bending or bending elements can also be used, such as those known from desk lamps. The swivel mechanism described can enable a simple but efficient and robust coupling of the sample separation device to the sliding element. A detailed example is in the 12 and 13 shown.

In this context, the term “fluidic connector” can in particular refer to an element that is intended to form a fluidic (and in particular fluid-tight, in particular high-pressure-tight) connection with an inlet or outlet of the sample separation device. In particular, such a fluidic connector can be designed as a fitting.

In this context, the term “fluidic interface” can in particular refer to an inlet section or an outlet section of a sample separation device, such as a chromatographic separation column. Such a fluid interface can be designed to establish a fluid connection with a fluid connection of a mounting device (on the sliding element and/or temperature control chamber).

In this context, the term “pivoting mechanism” can in particular refer to an action of pivoting a pivotable first fluidic connector (in particular together with a sample separation device mounted on the first fluidic connector) between predefined orientations, in particular a coupling orientation and an alignment orientation . Preferably, the sample separation device can be connected to the first fluidic connector and function as a rotary lever during such a pivoting process.

According to one exemplary embodiment, the sliding element has a holding element (in particular a spring element). This can be attached to the second coupling area for, in particular, soluble holding of the fluid temperature control device. This enables stable and flexible coupling of the fluid temperature control device. In one exemplary embodiment, the holding element can be designed as a click-in element, for example at least partially annular (if the fluid temperature control device is designed to be column-shaped). In a further example, the first coupling region can also have a holding element for holding the sample separation device. In one example, the holding element can have or consist of silicone.

According to one exemplary embodiment, the sliding element has a pressing element which is set up to exert pressure on the fluid temperature control device, in particular by means of a spring force. This enables a stable coupling of the sliding element with the fluid temperature control device, also with regard to a corresponding sliding device. In a special example, the pressure element can be designed as a leaf spring. Pressing can be an active process. In one example, the pressing element is used to press the fluid temperature control device onto the corresponding sliding device (on which it is moved). Pressing can be important to enable thermal coupling between the fluid temperature control device and the oven (temperature chamber); in other words: the sliding element presses the temperature control device against a heat block.

According to one exemplary embodiment, the sliding element has a handling element which enables manual and/or automatic handling, in particular when moving, of the sliding element. For example, the handling element can be designed as a handle so that the sliding element can be pulled or pushed in a simple manner.

According to one exemplary embodiment, the sliding element has a coupling element which is set up to couple the sliding element to a (corresponding) sliding device, in particular wherein the coupling element can be switched between a displaceable mode and a non-displaceable mode. The coupling element can be designed, for example, as a snap-in/click-in mechanism. For example, a sliding device can have corresponding counter structures into which the coupling element can be coupled. In one example, the sliding element can thereby be fixed (temporarily) in a specific position. The coupling element can thus enable a stable (releasable) attachment during displacement, for example in the vertical direction.

According to one exemplary embodiment, the sliding element has a guide element, which is set up in interaction with a guide structure, in particular a guide rail, to provide guidance for the sliding element during displacement. Such an interaction between the guide element and the guide rail can enable a defined and therefore efficient and safe displacement path. In a further example, the sliding element can also have a guide rail, which interacts with corresponding guide elements of the sliding device.

According to one embodiment, the sample separation device has: a separation fluid path with a separation path input and a separation path output, the sample separation device being set up to separate a fluidic sample between the separation path input and the separation path output. Accordingly, established (and standardized) separation columns can be used directly.

According to one embodiment, the fluid temperature control device has: a temperature control fluid path with a fluid inlet and a fluid outlet, wherein the fluid temperature control device is set up for pre-temperature control of the fluid (the fluidic sample) between the fluid inlet and the Fluid outlet (in a temperature control path, e.g. a capillary). Accordingly, established (and standardized) temperature control devices can be used directly.

According to one embodiment, the sliding element arrangement has: the (separation path inlet) fluid connector for fluidly connecting the fluid outlet of the fluid temperature control device to the separation path inlet of the sample separation device, in particular so that a flow path of the fluidic sample first reaches the fluid temperature control device and then passes through the sample separation device. Such a fluid connector can fluidly connect the sample separation device and the fluid temperature control device to one another directly on the sliding element. The fluid connector can be implemented, for example, as a capillary, channel or conduit.

According to one embodiment, the sliding element or the sliding element arrangement is ESD (electro-static discharge) protected when inserted into the temperature control chamber. This can improve accuracy/reliability. With an additional discharge step or a charge test, it can be ensured that the sliding element (or the arrangement) is free of electrical charge or is not electrically charged.

According to one embodiment, the sample separation device is longer in at least one spatial direction (in particular in the main extension direction) than the sliding element. According to one embodiment, the fluid separation device is shorter than the sliding element in at least one spatial direction (in particular in the main extension direction).

According to an exemplary embodiment, at least one of the sliding element, the sample separation device, the fluid temperature control device, has a preferred direction, in particular at least two of the preferred directions being aligned parallel to one another.

The term “preferred direction” here can refer to a main extension direction. For a separation column, the preferred direction can extend, for example, along (the flow path) of the column. The same applies to the temperature control path of an elongated fluid temperature control device. In a preferred example, the main extension directions of the sample separation device and fluid temperature control device can be (substantially) parallel to one another on the sliding element.

According to an exemplary embodiment, the sliding element arrangement further comprises: a tag which is associated with the sample separation device (and/or the fluid temperature control device), in particular coupled to the sample separation device, in particular wherein the tag has at least one of an NFC tag, an RFID Tag, a Bluetooth tag (a BLE beacon). Using such a tag, a sample separation device can be characterized/assigned. For example, it can be checked whether the correct sample separation device was inserted in the correct position.

According to one embodiment, the sliding element arrangement further comprises: a tag reader, which is associated with the sliding element (or the analysis device), in particular coupled to the sliding element (or the analysis device), in particular wherein the tag reader has at least one of one NFC tag reader, an RFID tag reader, a Bluetooth (a BLE beacon) reader.

Column tags (e.g. RFID tags or tags with electrical contacts) are typically attached to the column with a wire and coupled to a tag reader located outside the column oven. Due to inaccuracy, e.g. in the positioning of the column, the tag can lead to errors due to incorrect assignment (especially when placing multiple columns next to each other). For example, a tag with a plastic part is clicked onto a column or column position. However, this can affect the thermal performance of the column oven and the tag must be manually moved and aligned to the correct position of the corresponding tag reader antenna within the analyzer. In summary, it is a challenge in the prior art to provide an efficient coupling between tag and tag reader in an analysis device.

However, in conjunction with the sliding element, this need can be solved in an elegant and reliable manner. A day at the rehearsal The racing device is automatically attached to the sliding element in the correct position. When inserted into the analysis device, the tag is automatically brought into the correct position and orientation together with the sample separation device. The tag can thus be automatically aligned with the tag reader and (essentially) no manual interaction is required. The following advantages can arise: the assignment to within the analysis device is clear. No feedthrough interface for column tag wires is required (no holes in the column oven thermal insulation). The small size and low thermal mass of the tag have a negligible impact on the thermal behavior of the column. The thermal performance of the column oven is not affected by large parts (here the tags or antennas) on the surface of the sample separation device or antennas near the column body (no shields for thermal radiation and no blockage of airflow).

In addition to these advantages, it may be possible to detect whether the sample separation device is installed in the correct liquid flow direction (automatic detection of orientation when a tag is installed). In addition, it may be possible to attach a temperature sensor directly to the body of the sample separation device (or to the sliding element) in order to improve the temperature reference point for temperature control of the temperature chamber.

The described tag applications in conjunction with the sliding element can offer various advantages compared to the prior art, since the tag can be mounted directly on/on the sample separation device and is compatible with most available sample separation devices. The tag reader can be installed in the temperature chamber, which can prevent misalignment of the position (and a docking port). In addition, the correct orientation of the sample separation device can be monitored in this way. A simple structure with low cost can be realized. This allows (automatic) identification and monitoring of the sample separation device and/or fluid temperature control device (with low complexity).

According to one exemplary embodiment, the tag and the tag reader are arranged in the sliding element arrangement so that they can communicate with each other (in particular wirelessly). The reader can be coupled to the analysis device or a control unit of the analysis device in order to enable a power supply and/or data exchange. In a preferred application, the reader can supply the tag with the necessary energy to enable reading.

According to one exemplary embodiment, the analysis device has a temperature control chamber, in particular a column oven. According to one embodiment, the sliding element and/or the sliding element arrangement is displaceable (e.g. in or out) in relation to the temperature control chamber. According to one exemplary embodiment, the temperature control device is set up in such a way that the sliding element and/or the sliding element arrangement can be at least partially inserted into and/or executable from an interior of the temperature control chamber. As already described above, this can significantly simplify the introduction/connection of the sample separation device and fluid temperature control device.

According to one exemplary embodiment, the analysis device, in particular the temperature control chamber, has an opening, in particular a closable one, through which the displacement takes place. This allows the temperature control chamber to be insulated efficiently and reliably. The opening (e.g. a door) can be opened briefly to insert the sliding element and then closed again. A particularly small opening can be provided in an insertion direction into the depth of the analysis device (in the direction away from the operator).

According to one exemplary embodiment, the displacement takes place in a horizontal or vertical spatial direction. According to one exemplary embodiment, the sample separation device in the temperature control chamber is arranged horizontally or vertically during operation. A sample separation device is usually arranged horizontally (main extension direction perpendicular to the direction of gravity) in an analysis device. Accordingly, the sliding element can be implemented directly into existing systems. However, configurations can also be provided in which the sample separation device is arranged vertically. Here, the sliding element can push the sample separation device particularly efficiently to the desired position, in particular with the sample separation device being held against gravity.

Conventionally, temperature control chambers/column ovens are designed to save space. However, this results in disadvantages in terms of reduced capacity for sample separation devices (eg only one column and/or limitations in column length) or limitations in user-friendliness. For example, if a single column length requirement of 300 mm + guard column, user-friendly column connections + insulation, etc. are desired, the column oven would be very large Small dimensions in the front area and plenty of free space in the area behind are necessary. However, in order to reduce the space required or the required footprint of the instrument, the design of an analysis device generally aims at a low overall height for better usability and a smaller width. However, the depth of the analysis device is generally not of great interest and could therefore be expanded.

In one embodiment, a temperature control device can be constructed in such a way that the sample separation devices are oriented not along the width but along the depth. This allows better utilization of space without restricting the length of the sample separation device. Such positioning can be achieved in an advantageous manner by means of the sliding element. Instead of opening the temperature control chamber to fix the sample separation device along the width of the analysis device, the sample separation device can simply be pushed into the depth of the analysis device. In an example, the operator's viewing direction would correspond to the sliding direction.

This can result in the following advantages: reducing the space consumption/requirement of the analysis device; small (not large) door components that obscure other user interfaces or instruments located adjacent to the analyzer; shorter door seals (seals can be potential thermal weak points); no compromises between scope and space limitations.

Furthermore, the following advantages can be provided: more efficient use of space; optimized user interface, easy to build with less material; no large doors that could obscure user interfaces or create large thermal gaps; no restrictions on the area of application (column length; possibility of using guard columns; user-friendly connection solutions); two columns do not require much more space than one column; a valve for column switching (needed for more than one column).

According to an exemplary embodiment, the analysis device further has: a sliding device which is set up to act as a base when moving the sliding element and/or the sliding element arrangement, in particular wherein the sliding device is at least partially designed as a heat exchanger. According to an exemplary embodiment, the analysis device further has: a guide structure which is set up to guide at least part of the sliding element and/or the sliding element arrangement during displacement, in particular wherein the guide structure is set up to at least partially accommodate the fluid temperature control device. According to one exemplary embodiment, the guide structure and/or the fluid temperature control device has a triangular cross section in the preferred direction.

Advantageously, an existing and established structure can be repurposed to implement the sliding element. A surface of the heat exchanger can be used, for example, as a sliding device, and additional guide rails can be provided for the sliding element. The fluid temperature control device can be optimally arranged and tempered in the guide structure (even while moving).

According to one embodiment, the analysis device is designed as a sample separation device. According to one embodiment, the analysis device has a fluid drive for driving a mobile phase and a fluidic sample injected into the mobile phase. According to one embodiment, the analysis device has a sample separation device for separating the fluidic sample injected into the mobile phase. According to one embodiment, the analysis device is configured to analyze at least one physical, chemical and/or biological parameter of the fluidic sample. According to one embodiment, the analysis device is configured as a sample separation device for separating the fluidic sample.

In the context of the present application, the term “sample separation device” can be understood in particular as a device for analyzing a fluidic sample, in particular into different fractions. For this purpose, components of the fluidic sample can first be adsorbed on the sample separation device and then desorbed separately (in particular fractionally). For example, such a sample separation device can be designed as a chromatographic separation column.

According to one embodiment, the analysis device is a chromatography device, in particular a liquid chromatography device, a gas chromatography device, an SFC (supercritical liquid chromatography) device or an HPLC (high-performance liquid chromatography) device.

According to one embodiment, the analysis device is configured as a microfluidic device. According to one embodiment, this is Analysis device configured as a nanofluidic device.

According to one exemplary embodiment, the sample separation device is designed as a chromatographic separation device, in particular as a chromatography separation column.

According to one embodiment, the fluid drive is configured to drive the mobile phase and the fluidic sample under high pressure.

According to one embodiment, the fluid drive is configured for driving the mobile phase and the fluidic sample with a pressure of at least 200 bar, in particular at least 500 bar, in particular at least 1000 bar, more particularly at least 1200 bar, more particularly at least 1500 bar.

According to one exemplary embodiment, the analysis device has a detector for detecting the analyzed, in particular separated, fluidic sample.

According to one embodiment, the analysis device has a fractionator for fractionating separate fractions of the fluidic sample.

The analysis device can be a microfluidic measuring device, a life science device, a liquid chromatography device, a gas chromatography device, an HPLC (high performance liquid chromatography), a UHPLC system or an SFC (supercritical liquid chromatography) device. However, many other applications are possible.

According to one exemplary embodiment, the sample separation device can be designed as a chromatographic separation device, in particular as a chromatography separation column. In the case of a chromatographic separation, the chromatographic separation column can be provided with an adsorption medium. The fluidic sample can be stopped at this and only then be detached fractionally again in the presence of a specific solvent composition, thereby accomplishing the separation of the sample into its fractions.

A pump system for conveying fluid can, for example, be set up to convey the fluid or the mobile phase through the system at a high pressure, for example a few 100 bar up to 1000 bar and more. The analysis device can have a sample injector for introducing the sample into the fluidic separation path. Such a sample injector can have a sample or injection needle that can be coupled to a needle seat in a corresponding liquid path, whereby the sample needle can be moved out of this needle seat in order to take up sample. After reinserting the sample needle into the needle seat, the sample can be in a fluid path that can be switched into the separation path of the system, for example by switching a valve. In another embodiment of the invention, a sample injector or sampler can be used with a sample needle that is operated without a needle seat.

The analysis device may have a fraction collector for collecting the separated components. Such a fraction collector can, for example, lead the various components of the separated sample into different liquid containers. The analyzed sample can also be fed to a drain container.

Preferably, the analysis device can have a detector for detecting the separated components. Such a detector can produce a signal that can be observed and/or recorded and which is indicative of the presence and amount of the sample components in the fluid flowing through the system.

According to an exemplary embodiment, a sampling space is delimited by a housing in which the sample handling arrangement or sample movement device is arranged.

According to one embodiment, the sample separation device (column) is arranged in the user's viewing direction (the insertion direction would then also be in the user's viewing direction). In a further exemplary embodiment, the orientation of the sample separation device in the temperature control chamber/on the sliding element is perpendicular to the direction in which the user is viewing. In both cases, the sample separation device extends in a horizontal direction. In a further example, the sample separation device is arranged vertically or is inserted in the vertical direction.

BRIEF DESCRIPTION OF THE FIGURES

• 1 zeigt eine Analysevorrichtung konfiguriert als Chromatografiegerät, gemäß einem exemplarischen Ausführungsbeispiel der Erfindung.
• 2 zeigt eine Schiebeelement Anordnung mit einer Probentrennvorrichtung, gemäß einem exemplarischen Ausführungsbeispiel der Erfindung.
• 3 zeigt eine Schiebeelement Anordnung mit einer Fluid-Temperiervorrichtung, gemäß einem exemplarischen Ausführungsbeispiel der Erfindung.
• 4 zeigt eine Schiebeelement Anordnung an einer Schiebevorrichtung einer Analysevorrichtung, gemäß einem exemplarischen Ausführungsbeispiel der Erfindung.
• 5 zeigt einen Querschnitt durch das Ausführungsbeispiel von 4.
• 6 zeigt detailliert Strukturen eines Schiebeelements, gemäß einem exemplarischen Ausführungsbeispiel der Erfindung.
• Die 7A bis 7D zeigen ein Einführen einer Probentrennvorrichtung und einer Fluid-Temperiervorrichtung mittels eines Schiebelements in eine Temperierkammer einer Analysevorrichtung, gemäß einem exemplarischen Ausführungsbeispiel der Erfindung.
• 8 zeigt eine Schiebeelement Anordnung an einer Schiebevorrichtung mit Führungsschiene einer Analysevorrichtung, gemäß einem exemplarischen Ausführungsbeispiel der Erfindung.
• Die 9A und 9B zeigen ein Anschlusselement mit Schwenk-Mechanismus, gemäß einem exemplarischen Ausführungsbeispiel der Erfindung.
• Die 10A und 10B zeigen eine Analysevorrichtung mit Temperierkammer, gemäß einem exemplarischen Ausführungsbeispiel der Erfindung.
• 11 zeigt eine Schiebeelement Anordnung mit einem Tag und einem Tag-Reader, gemäß einem exemplarischen Ausführungsbeispiel der Erfindung.
• Die 12 und 13 zeigen detailliert den Schwenk-Mechanismus, gemäß einem exemplarischen Ausführungsbeispiel der Erfindung.

Other objects and many of the attendant advantages of embodiments of the present invention will become readily apparent and better understood by reference to the following more detailed description of embodiments taken in conjunction with the accompanying drawings. Features that essentially or are functionally the same or similar are given the same reference numerals.

• 1 shows an analysis device configured as a chromatography device, according to an exemplary embodiment of the invention.
• 2 shows a sliding element arrangement with a sample separation device, according to an exemplary embodiment of the invention.
• 3 shows a sliding element arrangement with a fluid temperature control device, according to an exemplary embodiment of the invention.
• 4 shows a sliding element arrangement on a sliding device of an analysis device, according to an exemplary embodiment of the invention.
• 5 shows a cross section through the exemplary embodiment of 4 .
• 6 shows detailed structures of a sliding element, according to an exemplary embodiment of the invention.
• The 7A to 7D show an introduction of a sample separation device and a fluid temperature control device by means of a sliding element into a temperature control chamber of an analysis device, according to an exemplary embodiment of the invention.
• 8th shows a sliding element arrangement on a sliding device with a guide rail of an analysis device, according to an exemplary embodiment of the invention.
• The 9A and 9B show a connection element with a pivoting mechanism, according to an exemplary embodiment of the invention.
• The 10A and 10B show an analysis device with a temperature control chamber, according to an exemplary embodiment of the invention.
• 11 shows a sliding element arrangement with a tag and a tag reader, according to an exemplary embodiment of the invention.
• The 12 and 13 show in detail the pivoting mechanism, according to an exemplary embodiment of the invention.

DETAILED DESCRIPTION OF THE FIGURES

The representation in the drawing is schematic.

1 shows the basic structure of an HPLC system as an example of an analysis device 10 designed as a sample separation device or chromatography device, according to an exemplary embodiment of the invention, as can be used for liquid chromatography, for example. A fluid conveyor or fluid drive 20, supplied with solvents from a feeder 25 (or consumables from a container), drives a mobile phase through a sample separation device 30 (such as a chromatographic column) containing a stationary phase.

The solvents are here a consumable material which is stored in one or more containers 25. The supply device usually comprises a first fluid component source (e.g. first container) for providing a first fluid or a first solvent component A (e.g. water) and a second fluid component source (e.g. second container) for providing another second fluid or a second solvent component B (for example an organic solvent).

An optional degasser 27 can degas the solvents provided by the first fluid component source and by the second fluid component source before they are supplied to the fluid drive 20. A sample application unit, which can also be referred to as an injector 40 (sampler), is arranged between the fluid drive 20 and the sample separation device 30 in order to first receive a sample liquid or a fluidic sample from a sample container into a sample receiving volume in an injector path, and subsequently by switching an injection valve of the injector 40 into a fluidic separation path between the fluid drive 20 and the sample separation device 30. The collection of fluidic sample from the sample container can be done in particular by moving a sample needle out of a sample seat and moving it into the sample container, sucking fluidic sample from the sample container through the sample needle into the sample receiving volume by means of a fluid delivery device designed as a dosing device, and the sample needle then moved back into the needle seat.

The stationary phase of the sample separation device 30 is intended to separate components of the sample. The sample separation device 30 is arranged in a temperature control chamber 160 (or a column oven). The fluid path from the fluid drive 20 is coupled to an input 92 of the sample separation domain, while an output 96 of the sample separation domain is coupled to a detector 50. The sample separation device 30 is on a sliding element ment 150 coupled (thus a sliding element arrangement 100). A first fluidic connector 102 of the input 92 is coupled to a first fluidic interface 104 of the sample separation device, while an opposite second fluidic interface 108 of the sample separation device is coupled or can be coupled to a second fluidic connector 106 of the output 96.

The detector 50, which may include a flow cell, detects separated components of the sample. A fractionation device or fractionator 60 may be provided to dispense separated components of the sample into designated containers. Liquids that are no longer needed can be dispensed into a drain container or waste line.

While a liquid path between the fluid drive 20 and the sample separation device 30 is typically under high pressure, the sample liquid under normal pressure is first introduced into an area separate from the liquid path, namely the sample loop or the sample receiving volume, of the sample application unit or the injector 40. The sample liquid is then introduced into the high-pressure separation path. A sample loop as a sample receiving volume (also referred to as a sample loop) can be understood as a section of a fluid line that is designed to receive or temporarily store a predetermined amount of fluidic sample. Preferably, before the sample liquid, which is initially under normal pressure, is switched on in the sample receiving volume into the high-pressure separation path, the contents of the sample receiving volume are brought to the system pressure of the analysis device 10 designed as HPLC by means of a metering device in the form of the fluid conveying device. A control device or a control system 70 controls the individual components or elements 20, 25, 30, 40, 50, 60, etc., of the analysis device 10. Each of these components can have a separate housing, or two or more components can be in the same Housing be arranged.

2 shows a sliding element arrangement 100 with a sample separation device 30, according to an exemplary embodiment of the invention. The sliding element 150 has a first coupling region (top) on a first main surface (top) for coupling the sample separation device 30. The sample separation device 30 is coupled or connected to the first coupling area in order to provide the sliding element arrangement 100. The sliding element 150 is set up to bring the sample separation device 30 into a position relative to a temperature control chamber 160 of the analysis device 10 when it is moved. In particular, the sample separation device 30 should be inserted (or pushed out) into the temperature control chamber 160 by means of the sliding element 150 in order to enable efficient and user-friendly insertion and connection of the sample separation device 30.

The sliding element 150 further has a second coupling area on a second main surface (underside) for coupling a fluid temperature control device (see detailed in 3 below). The second main surface is arranged opposite and parallel to the first main surface. Holding elements 151 are provided to fasten the fluid temperature control device. Furthermore, a coupling element 155 is provided for coupling to a corresponding sliding device.

The sliding element 150 has a connection element 130, which is connected to the input of the sample separation device 30. In particular, a first fluidic connector 102 (here the for 7 , 9 , 12 and 13 The pivoting mechanism described can be used) on the sliding element 150, which is coupled to a first fluidic interface 104 of the sample separation device 30. The coupling between sample separation device 30 and sliding element 150 is mechanical. The fluidic coupling (with the fluid drive 20) takes place via the fluid connector 31 (separation path input fluid path). This connection can be coupled to the first fluidic interface 104 and runs at least partially through the connection element 130.

3 shows a sliding element arrangement 100 with a fluid temperature control device 110, according to an exemplary embodiment of the invention. The sliding element 150 is similar to for 2 constructed as described and coupled to the sample separation device 30 as described above. The fluid temperature control device 110 is now additionally coupled to the second main surface (underside) (for example to the holding elements 151). The sliding element 150 is therefore set up to bring the sample separation device 30 and the fluid temperature control device 110 together into the desired position with respect to the temperature control chamber 160 of the analysis device 10 when moving.

The fluid temperature control device 110 has a fluid inlet 111, which can be coupled, for example, to the flow path of the fluid drive 20. Downstream, the fluid temperature control device 110 has a fluid outlet 112, which can be fluidly connected to the first fluidic interface 104 via the fluid connector 31. A temperature-controlled fluid therefore runs through the fluid temperature control device 110 Fluid path 115 in which the fluid can be pre-tempered.

In 3 The separation path output 32 of the sample separation device 30 is also shown. A second fluidic interface 108 is also located here. The sample separation device 30 is significantly longer than the sliding element 150 (and the fluid temperature control device 110). Nevertheless, the sample separation device 30 can be stably coupled and moved, and the length of the sample separation device 30 can be very flexible.

4 shows a sliding element arrangement 100 on a sliding device 170 of an analysis device 10, according to an exemplary embodiment of the invention. As for 2 described above, the sample separation device 30 is coupled to the sliding element 150 and can be moved with it. The corresponding sliding device 170, which has a triangular cross section, is provided in the temperature control chamber 160 of the analysis device 10. The fluid temperature control device 110 can be arranged and moved within this triangular cross section (guide structure 171) (not shown here, see 3 and 5 ). The sliding device 170 can be part of a heat exchanger and has guide rails 172, by means of which the sliding element 150 can be displaced in a defined manner.

The coupling element 155 of the sliding element 150 described above can be used to couple the sliding element 150 to the sliding device 170. The sliding element 150 can be guided by the guide rails 172 when moving. For this purpose, the sliding element can be a guide element 156 (see detailed 8th ) exhibit. In one example, the coupling element 155 can be switchable between a displaceable mode and a non-displaceable mode, or can be fixed or released in a certain position.

5 shows a cross section through the exemplary embodiment of 4 . Here the structure of the sliding device 170 can be seen more clearly, which has a heat exchanger and a triangular guide structure 171 in cross section. The fluid temperature control device 110 is arranged in this guide structure 171 and is attached to the sliding element 150 by means of the holding elements 151 (here clip rings). attached. In this example, the sliding element 150 rests on the sliding device 170. It can be seen that coupling elements 155 of the sliding element 150 are inserted into corresponding coupling structures (rails) 172 of the sliding device 170, so that the sliding element 150 can be displaced in a defined manner and is stably (but releasably) attached. Furthermore, pressing elements 152 are provided on the sliding element 150, by means of which the second main surface (underside) of the sliding element 150 presses the fluid temperature control device 110 onto the sliding device 170.

6 shows detailed structures of a sliding element 150, according to an exemplary embodiment of the invention, with the view directed towards the second main surface (underside). The holding elements 151 for the fluid temperature control device 110 have already been described in the examples above. The coupling elements 155 have also already been described, by means of which the sliding element 150 can be coupled to a sliding device 170. In particular, snapping can be carried out, which enables a stable, but still movable, coupling. The pressure elements 152 can be designed as (leaf) springs. Furthermore, the sliding element 150 has a handling element 153, which is implemented here as a handle. This handling element 153 can be used manually or automatically to actively move the sliding element 150 (along the sliding device 170).

The 7A to 7D show an introduction of a sample separation device 30 and a fluid temperature control device 110 by means of a sliding element 150 (i.e. as a sliding element arrangement 100) into a temperature control chamber 160 of an analysis device 10, according to an exemplary embodiment of the invention. The direction of insertion into the temperature control chamber 160 is shown here horizontally (along X or along Y). However, the temperature control chamber 160 can also be oriented vertically, so that the sliding element 150 is inserted in the vertical direction (along Z).

7A : the sliding element 150 described above with coupled fluid temperature control device 110 is provided. The connection element 130 is tilted (pivoted) upwards to enable coupling with the sample separation device 30. The first fluidic interface 104 of the sample separation device 30 is brought into physical contact with the first fluidic connector 102. An arrow indicates that the first fluidic interface 104 has a turn which is screwed onto a screw connector 102. This enables a robust and easy-to-use connection.

7B : the (movable) connecting element 130 is now pivoted (tilted) downwards, so that the coupled sample separation device 30 moves from a first position, with a 45° orientation to the main surface of the sliding element 150, to a second position, with a 0° orientation (parallel) to the main surface of the sliding element 150 is moved. (and the fluid connector is closed under high pressure).

7C : the sample separation device 30 is now arranged parallel to the main extension directions of the sliding element 150 and fluid temperature control device 110. This sliding element arrangement 100 should now be inserted into the temperature control chamber 160 in a horizontal (alternatively vertical) direction. This is illustrated by the arrow S. The sliding direction can be in the depth of the analysis device 10, i.e. in the direction the operator is looking away from the operator.

7D : The sliding element arrangement 100 is now arranged at the desired position in the temperature control chamber 160.

8th shows a sliding element arrangement 100 on a sliding device 170 with guide element 156, according to an exemplary embodiment of the invention. 8th is comparable to the 4 and 5 and shows in detail the interaction of guide element 156 and guide rail 172 of the sliding device 170. Guide element 156 and coupling element 155 can be identical in this example.

The 9A and 9B show a connection element 130 with a pivoting mechanism, according to an exemplary embodiment of the invention.

9A : the sliding element 150 is shown upright and the connecting element 130 is attached to the first main surface (top). This has the first fluidic connector 102 for coupling to the first fluidic interface (input) of the sample separation device 30. As for 7 already described, the first fluidic connector 102 has a screw connector for mechanical screwing. Furthermore, the sliding element 150 has the fluid connector 31 connection, which enables the fluidic connection.

9B In order to implement the pivoting mechanism, the first fluidic connector 102 is designed to be movable and in this example can be tilted (designed) by more than 90° in relation to the main surface of the sliding element 150 in order to enable easy coupling of the sample separation device 30.

The 10A and 108 show an analysis device 10 with a temperature control chamber 160, according to an exemplary embodiment of the invention. As for 1 already described, an analysis device 10 can have the following units, which in the case of HPLC are usually stacked on top of one another in a vertical direction: fluid drive 20, sample injector 40, temperature control chamber (column oven) 160, detector 50, solvent container 25.

10A : It is shown schematically that a sliding element 150 with two sample separation devices 30 is inserted into the temperature control chamber 160. Unlike in the prior art, the sample separation devices 30 are not arranged along the width (X), but are pushed vertically into the depth (Y). As a result, two or more sample separation devices 30 can be arranged in a (small) column oven 160 in a particularly space-saving manner. To the right of the sliding element arrangement 100, a switching valve is schematically illustrated, which is necessary in the case of two of the more sample separation devices 30.

10B : In this implementation, sample injector 40 and temperature control chamber 160 are installed together. This is achieved by inserting only one sample separation device 30 (on a corresponding sliding element 150) in the viewing direction of the operator to save space.

11 shows a sliding element arrangement 110 with a tag 180, according to an exemplary embodiment of the invention. Due to the defined position of the sample separation device 30 on the sliding element 100, a fixed length L (or offset) can be maintained. In other words, the position of the tag 180 on the sample separation device 30 can be precisely determined. Electrical contacts 182 (e.g. contact pins) can electrically connect the tag 180 to the sliding element 150 (via contact areas 181.

In a specific example, a tag/EEPROM 180 is placed on a label/flexboard that is insulated from and wrapped around the column 30 and includes plated metallic contact pads (preferably gold) surrounding the cylindrical surface of the column 30. The label could be constructed as an adhesive label/sticker that can be wrapped around the column 30. Flexboards or similar processes as with RFID tag labels can be used to produce the conductive layers. The sliding element 150 here has spring-loaded contact pins 182, which have a defined offset to the column entry point 104 and a connection to the electrical contact surfaces 181 on the column 30 produce.

In one example, tag 180 is a component that only requires two connection pins to simplify the connection effort (e.g. one-wire EEPROM). To counteract the risk of corrosion (solvent vapors), two gold contacts can be used for each contact surface and the surfaces can be designed to be rough and free of surface contamination.

The pins 182 and also the sliding element 150 can be inexpensive and can be replaced regularly. Such a design makes it possible, for example, to cut a barcode or a readable serial number into the metallic surface with a laser (or to add a normal sticker with this information). A self-destruction of tag 180 when removed from column 30 can be implemented. The same tag 180 can be used for columns of different types, e.g. with different diameters/lengths.

The sliding element 150 means that no manual alignment of the tag 180 is required. With appropriate design, the column orientation can be recorded with low thermal load. No complex antenna-based systems are required for this, so that no regulatory problems arise, e.g. with RFID. Optionally, a temperature sensor can be added to the column 30 or to the sliding element 150.

The 12 and 13 show the pivoting mechanism, which is realized by means of the connecting element 130 of the sliding element 150, according to an exemplary embodiment of the invention. The sliding element 150 has the first fluidic connector 102 on the connection element 130, set up for fluidic coupling with a first fluidic interface 104 of the sample separation device 30 (designed as a hinge element). Furthermore, the sliding element 150 has a second fluidic connector 106, set up for fluidic coupling with a second fluidic interface 108 of the sample separation device 30. The pivoting mechanism is set up for pivoting the first fluidic connector 102 between a coupling orientation for coupling the first fluidic Interface 104 on the first fluidic connector 102 and an alignment orientation for aligning the sample separation device 30.

12 shows the coupling orientation (compare 7A and 9B) . In a first step (1), the sample separation device 30 is coupled or screwed to the connection element 130. In a second step (2), the connected sample separation device 30 is tilted from the coupling orientation into the alignment orientation.

13 shows the alignment orientation (compare 7C and 9A) . In a third step (3), the second fluidic connector 106 (of the temperature control chamber 160) is adjusted to the length of the sample separation device 30. This allows a variety of different column lengths to be used. The adjusted position of the second fluidic connector 106 is fixed by means of a lever 114. This means that the sample separation device 30 (coupled to the sliding element 150) is connected to the desired position in the temperature control chamber 160 of the analysis device 110.

Reference symbols

10

Analysis device

20

Fluid propulsion

25

Feeding device, container

27

Degasser

30

Sample separation device

31

Isolation path input fluid path, fluid connector

32

Isolation path output

40

injector

50

detector

60

fractionator

70

Control device

92

Input sample separation domain

96

Output sample separation domain

100

Sliding element arrangement

102

First fluidic connector

104

First fluidic interface (fluidic connection/input)

106

Second Fuidian connector

108

Second fluidic interface (fluidic output)

110

Fluid temperature control device

111

Fluid input

112

Fluid output

114

lever

115

Temperable fluid path

130

Connection element, swivel mechanism

131

Fixing mechanism

150

Sliding element

151

Holding element

152

Pressure element

153

Handling element

155

Coupling element

156

Leadership element

160

Temperature chamber, column oven

170

Sliding device

171

Leadership structure

172

Guide rail

180

Day

181

Electrical contact area

182

Contact pin

S

Sliding direction

QUOTES INCLUDED IN THE DESCRIPTION

This list of documents listed by the applicant was generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• EP 0309596 B1 [0003]

Claims (20)

A sliding element (150) for an analysis device (10), wherein the analysis device (10) is designed in particular as a sample separation device for separating a fluid sample in a sample separation device (30), in particular a chromatographic separation column, and the sliding element (150) has: a first coupling area for coupling the sample separation device (30); wherein the sliding element (150) is designed to bring the coupled sample separation device (30) into a position with respect to the analysis device (10), in particular with respect to a temperature control chamber (160) of the analysis device (10), when moved. The sliding element (150) follows Claim 1 , comprising: a second coupling region for coupling a fluid temperature control device (110) for pre-temperature control of a fluid upstream of the sample separation device (30); wherein the sliding element (150) is designed to move the sample separation device (30) and the fluid temperature control device (110) together into a position with respect to the analysis device (10), in particular with respect to the temperature control chamber (160) of the analysis device (10). bring. The sliding element (150) follows Claim 1 or 2 , wherein the first coupling region has a first main surface which is set up for coupling the sample separation device (30); and/or wherein the second coupling region has a second main surface which is set up for coupling the fluid temperature control device (110); in particular, wherein the first main surface is arranged opposite the second main surface. The sliding element (150) follows Claim 2 or 3 , comprising: wherein the sliding element (150) is set up so that the sample separation device (30) and the fluid temperature control device (110) can be fluidically coupled to one another by means of a fluid connector (31), in particular so that the fluid temperature control device (110) is arranged in a flow path upstream of the sample separation device (30). The sliding element (150) according to any one of the preceding claims, further comprising: at least one connection element (130) on the coupling area for, in particular soluble, connection of the sample separation device (30). The sliding element (150) according to one of the preceding claims, wherein the connecting element (130) has at least one of the following features: a pivoting mechanism for fluidly and mechanically coupling the sample separation device (30) to the sliding element (150); wherein the sliding element (150) has a first fluidic connector (102) adapted for fluidic coupling to a first fluidic interface (104) of the sample separation device (30); wherein the sliding element (150) is designed to fluidly couple a second fluidic interface (108) of the sample separation device (30) to a second fluidic connector (106), in particular the temperature control chamber (160); wherein the pivoting mechanism is set up to pivot the first fluidic connector (102) between a coupling orientation for coupling the first fluidic interface (104) to the first fluidic connector (102) and an alignment orientation for aligning the sample separation device (30) ; wherein the pivoting mechanism has a hinge element. The sliding element (150) according to one of the preceding claims, further comprising at least one of the following features: a holding element (151), in particular a spring element, on the second coupling region for, in particular soluble, holding the fluid temperature control device (110); a pressure element (152), which is set up, in particular by means of a spring force, to exert pressure on the fluid temperature control device (110); a handling element (153), which enables manual and/or automatic handling, in particular when moving, of the sliding element (150); a coupling element (155), which is designed to couple the sliding element (150) to a sliding device (170), in particular wherein the coupling element (155) can be switched between a displaceable mode and a non-displaceable mode; a guide element (156), which is set up in interaction with a guide structure (171), in particular a guide rail (172), to provide guidance of the sliding element (150) during displacement. A sliding element arrangement (100) for an analysis device (10), the arrangement (100) comprising: a sliding element (150) according to one of the preceding claims; the sample separation device (30), which is coupled to the first coupling region of the sliding element (150); and or the fluid temperature control device (110), which is coupled to the second coupling region of the sliding element (150). The sliding element arrangement (100) according to Claim 8 , wherein the sample separation device (30) has: a separation fluid path with a separation path inlet (31) and a separation path outlet (32), wherein the sample separation device (30) is set up to separate a fluidic sample between the separation path inlet (31 ) and the separation path output (32). The sliding element arrangement (100) according to Claim 8 or 9 , wherein the fluid temperature control device (110) has: a temperature-controlled fluid path (115) with a fluid inlet (111) and a fluid outlet (112), the fluid temperature control device (110) being set up for pre-tempering the fluidic Sample between the fluid inlet (111) and the fluid outlet (112). The sliding element arrangement (100) according to Claim 9 or 10 , comprising: a fluid connector (31) for fluidly connecting the fluid outlet (112) of the fluid temperature control device (110) to the separation path inlet (31) of the sample separation device (30), in particular so that a fluid flows along the flow path first passes through the fluid temperature control device (110) and then the sample separation device (30). The sliding element arrangement (100) according to one of the Claims 8 until 11 , wherein at least one of the sliding element (150), the sample separation device (30), the fluid temperature control device (110) has a preferred direction, in particular a main extension direction, in particular wherein at least two of the preferred directions are aligned parallel to one another. The sliding element arrangement (100) according to one of the Claims 8 until 12 , further comprising: a tag (180) which is associated with the sample separation device (110), in particular coupled to the sample separation device (110), in particular wherein the tag has at least one of an NFC tag, an RFID tag, a Bluetooth tag; and/or a tag reader which is associated with the sliding element (150), in particular coupled to the sliding element (150), in particular wherein the tag reader has at least one of an NFC tag reader, an RFID tag reader, a Bluetooth reader; in particular, wherein the tag (180) and the tag reader are arranged in the sliding element arrangement (100) so that they can communicate with one another. An analysis device (10) for analyzing a fluidic sample, in particular to be injected into a mobile phase, the analysis device (10) comprising: a sliding element (150) and/or a sliding element arrangement (100) according to one of the preceding claims, wherein the sliding element (150) and/or the sliding element arrangement (100) is displaceable in relation to the analysis device (10). The analysis device (10) according to Claim 14 , further comprising: the temperature control chamber (160), in particular a column oven; wherein the sliding element (150) and/or the sliding element arrangement (100) is displaceable in relation to the temperature control chamber (160), in particular wherein the temperature control device (160) is set up in such a way that the sliding element (150) and/or the sliding element arrangement ( 100) can be at least partially inserted into and/or executable from an interior of the temperature control chamber (160). The analysis device according to Claim 14 or 15 , having at least one of the following features: wherein the analysis device (10), in particular the temperature control chamber (160), has an opening, in particular a closable one, through which the displacement takes place; the displacement takes place in a horizontal or vertical spatial direction; the displacement takes place into the depth of the analysis device; wherein the displacement occurs parallel to a line of sight of an operator; wherein the sample separation device (30) is arranged horizontally or vertically in the temperature control chamber (160) during operation. The analysis device (10) according to one of Claims 14 until 16 , further comprising: a sliding device (170), which is set up to act as a base when moving the sliding element (150) and / or the sliding element arrangement (100), in particular wherein the sliding device (170) is at least partially designed as a heat exchanger; and/or a guide structure (171) which is set up to guide at least part of the sliding element (150) and/or the sliding element arrangement (100) during displacement, in particular wherein the guide structure (171) is set up to support the fluid temperature control device (110 ) at least partially, further in particular wherein the guide structure (171) and / or the fluid temperature control device (110) has a triangular cross section to the preferred direction. The analysis device (10) according to one of the Claims 14 until 17 , further comprising at least one of the following features: the analysis device (10) is configured to analyze at least one physical, chemical and / or biological parameter of the fluidic sample; the analysis device (10) is configured as a sample separation device for separating the fluidic sample; the analysis device (10) is a chromatography device, in particular a liquid chromatography device, a gas chromatography device, an SFC (supercritical liquid chromatography) device or an HPLC (high-performance liquid chromatography) device; the analysis device (10) is configured as a microfluidic device; the analysis device (10) is configured as a nanofluidic device; the sample separation device (30) is designed as a chromatographic separation device, in particular as a chromatography separation column; the fluid drive (20) is configured to drive the mobile phase and the fluidic sample under high pressure; the fluid drive (20) is configured to drive the mobile phase and the fluidic sample with a pressure of at least 200 bar, in particular at least 500 bar, in particular at least 1000 bar, further in particular at least 1200 bar; the analysis device (10) has a detector (50) for detecting the analyzed, in particular separated, fluidic sample; the analysis device (10) has a fractionator (60) for fractionating separate fractions of the fluidic sample. A method for bringing a sample separation device (30) into a specific position in an analysis device (10), the method comprising: Coupling the sample separation device (30), in particular a chromatographic separation column, to a sliding element (150); and Moving the coupled sample separation device (30) to the specific position by means of the sliding element (150) in relation to the analysis device (10). Using a sliding element (150) according to one of Claims 1 until 7 and/or a sliding element arrangement (100) according to one of the preceding Claims 8 until 13 for introducing and/or executing a sample separation device (30) with respect to a temperature control chamber (160) of an analysis device (10).

Images