DE202022104567U1 - Sample container system - Google Patents

Abstract

Sample container system (1) for use in a pressure container (100), comprising:
a sample container (2).
- a sample container space (3) for holding a sample (P) and
- an edge (21) defining an opening (22); and
a lid (4) for closing the opening (22), the lid (4) having:
- a plug-in section (41), which can be inserted into the sample container (2) via the opening (22) and via which the lid (4) can be moved axially relative to the sample container (2),
- a flange (43), which extends radially outwards from the plug-in section (41) and, when the plug-in section (41) is inserted into the sample container (2), rests with a support side (44) on the edge (21). can, and
- A recess (46) which extends axially in an outer surface (42) of the plug-in section (41) and then radially outwards in the support side (44) of the flange, so that when the plug-in section (41) is inserted into the sample container (2). and the flange (43) rests with the support side (44) on the edge (21), the sample container space (3) is fluidically connected to the environment (U) of the sample container system (1) via the recess (46).

Description

The invention relates to a sample container system for use in a pressure container and a pressure container having such a sample container system.

Pressure reactions on samples are carried out, for example to analyze a sample. For this purpose, the sample is taken into a sample container, which is then exposed to a chemical and/or physical pressure reaction in a pressure container. With the sample container, the sample can be easily placed in the pressure container and easily removed from it again.

The pressure reaction on the sample can cause a pressure in the sample container to increase, for example due to an exothermic reaction taking place in the sample container. The pressure can increase in a disadvantageous manner. For example, an undesirably rapid increase in pressure can damage the sample container or cause other undesirable effects (damage to the sample, falsification of analysis results, etc.).

It is therefore an object of the present invention to overcome the disadvantages mentioned above, in particular to better regulate the pressure in a sample container.

This task is solved by the subject matter of the independent claims. Advantageous further training is the subject of the related subclaims.

According to a first aspect, the invention relates to a sample container system for use in a pressure vessel. The sample container system includes: a sample container having a sample container space for receiving a sample and a rim defining an opening; and a lid to close the opening. The lid has: a plug-in section which can be inserted into the sample container via the opening and via which the lid can be moved axially relative to the sample container; a flange which extends radially outwards from the plug-in section and, when the plug-in section is inserted into the sample container, can rest with one support side on the edge; and a recess which extends axially in an outer surface of the plug-in section and then radially outwards in the support side of the flange, so that when the plug-in section is inserted into the sample container and the support side of the flange rests on the edge, the sample container space extends over the recess is fluidly connected to the environment of the sample container system.

With the sample container system, the pressure prevailing in the sample container space can be regulated particularly easily. On the one hand, in the state in which the lid is inserted into the sample container via its plug-in section, via the fluidic connection provided by the recess between the environment (e.g. a gas that surrounds the sample container system in a reaction chamber of a pressure container, or ambient air) and the sample container space is supplied with a gas (e.g. a gas required for a reaction in the sample container space, for example to build up a pressure provided in the sample container space, preferably in the range from 10 to 60 bar) or also a gas (for example one produced in a reaction in the sample container space). Gas) must be removed from the sample container. On the other hand, the plug-in section inserted into the sample container can be moved axially through the opening due to excess pressure in the sample container space, whereby pressure equalization with the environment takes place. While the plug-in section moves axially through the opening, the recess is simultaneously moved through the opening, whereby the recess is at least partially exposed and thus an opening is enlarged through which a gas can flow out of the recess. If the lid is lifted due to an increasing excess pressure in the sample container space, a larger gas flow can flow out of the sample container space via the enlarged opening and thus a disadvantageous pressure curve and/or an undesirably high pressure in the sample container space can be prevented.

There is therefore in particular no risk that parts of the sample container system (in particular sample containers and/or lids) will be damaged due to a pressure drop between the environment and the sample container space. In addition, due to the design of the lid, pressure regulation in the sample container space can be carried out easily, in particular without the parameters of a pressure container (for example regulation of the pressure in a reaction chamber and/or the supply of a reaction gas) in which the sample container system is used having to be adjusted. The lid thus forms a so-called self-regulating lid or, in other words, a container closure with a valve effect.

If the plug-in section is inserted into the sample container, it is preferred if the lid is moved relative to the sample container at least between a first position and a is axially movable in the second position, with at least part of the recess being covered by the sample container in the first position and protruding beyond the edge in the second position and thereby being exposed. The lid can be moved from the first position to the second position by an increase in pressure in the sample container space, for example. In the first position, a gas preferably flows through the recess into the sample container space, in particular to bring about a pressure equalization between the environment and the sample container space and thereby prevent pressure deformation of the container. In the second position, due to the exposed part of the recess, in particular a gas flow that is larger than in the first position can leave the sample container space via the recess, whereby a pressure equalization between the environment and the sample container space can also be brought about, in particular if there is a pressure in the latter (e.g. due to a chemical reaction) increases. Pressure regulation in the sample container space is therefore particularly easy to provide.

The sample container preferably extends along a longitudinal axis, wherein, when the plug-in section is inserted into the sample container, the part of the recess running in the outer surface of the plug-in section runs at least partially parallel to the longitudinal axis. As a result, the recess can be moved particularly advantageously relative to the edge of the sample container, for example essentially vertically. This is particularly advantageous for pressure regulation in the sample container space. In addition, the recess can therefore be provided particularly easily in the outer surface of the plug-in section. The part of the recess running in the support side of the flange preferably extends perpendicular to the longitudinal axis of the sample container.

The recess is preferably slot-shaped. This means that the recess preferably has an elongated shape. The recess preferably consists of only one or more straight sections. For example, the recess can consist of only two straight sections, with the first section being provided in the support side of the flange and the second section being provided in the outer surface of the plug-in section.

The plug-in section preferably has a bottom side (i.e. a side that faces away from a top side of the lid) which, when the plug-in section is inserted into the sample container, delimits the sample container space, with the recess extending away from the bottom and/or extending from the bottom.

The plug-in section can be at least partially cylindrical and/or conical. The plug-in section can have a round (preferably circular) cross section. Seen in cross section (i.e. in a section perpendicular to the longitudinal axis of the plug-in section), the plug-in section preferably has a circumference delimiting the cross-section, which corresponds to a round (preferably circular) shape except for the point at which the recess is provided.

The lid can be at least partially made of plastic, the plastic preferably comprising: PTFE, quartz and/or glass. As a result, the lid can be easily manufactured on the one hand and, on the other hand, can advantageously withstand the conditions present in the sample container space (in particular the physical and/or chemical conditions, for example pressure, chemical substances, reactions).

When the plug-in section is inserted into the sample container and the support side rests on the edge, the flange is preferably flush with the edge. That is, viewed in the direction of the longitudinal axis of the sample container, the flange preferably does not extend beyond the edge. The sample container system is therefore particularly compact.

If the plug-in section is inserted into the sample container and the support side rests on the edge, the part of the recess running in the support side can protrude over the edge. In other words, in this inserted state, the recess can extend further radially outwards than the edge. The recess can thus be fluidly connected to the environment in a simple manner.

The sample container system can have a cover element (eg a cover disk or a lid) which is designed to prevent condensate from entering the recess, particularly in the form of drops. For example, the flange (seen in a side view or in the radial direction) may be provided between the cover element and the edge of the sample container. The cover element can be formed integrally with or separately from the lid. In one embodiment, the cover element can be placed on the lid. In addition, the cover element can be designed to prevent condensate from entering the recess of at least one further sample container system, which is designed as described above. The cover element is preferably designed so that the condensate flows (for example due to gravity) to an edge of the cover element and then at a defined distance from the sample container system (e.g. near a reactor or a reactor wall). The cover element in particular prevents contaminants from penetrating into the sample container space through the condensate and adversely affecting the sample received there. The cover element also improves the analysis carried out on the sample.

The sample container system can further have a stop element which is arranged to limit a stroke of the lid inserted into the sample container. In other words, the stop element can ensure that the lid can only be raised relative to the edge of the sample container along a defined maximum path. In particular, the stop element can be used to prevent the lid from falling out of the sample container or getting jammed. The stop element can also be used to define a maximum gap between the support side of the flange and the edge of the sample container and thus a maximum opening of the recess.

According to a second aspect, the invention relates to a pressure vessel. The pressure vessel has a sample container system as described above. For example, the pressure container can have a reaction chamber as a pressure space for triggering and/or promoting chemical and/or physical pressure reactions, with the sample container system being arranged in the reaction chamber. One or more sample container systems can be arranged in the pressure vessel, preferably in the reaction chamber. The multiple sample container systems can be held in a sample container holder (for example in the manner of a basket).

• 1 eine schematische Schnittansicht einer bevorzugten Ausführungsform des erfindungsgemäßen Probenbehältersystems, wobei der Deckel sich in einer ersten Stellung befindet;
• 2 eine schematische Schnittansicht der in 1 gezeigten Ausführungsform, wobei sich der Deckel in einer zweiten Stellung befindet; und
• 3 eine schematische Schnittansicht einer bevorzugten Ausführungsform des erfindungsgemäßen Druckbehälters, in dem mehrere Probenbehältersysteme, die jeweils gemäß der in den 1 und 2 bevorzugten Ausführungsform ausgebildet sind, vorgesehen sind.

The invention is described below by way of example using the figures in which preferred embodiments of the invention are shown. Show it:

• 1 a schematic sectional view of a preferred embodiment of the sample container system according to the invention, with the lid being in a first position;
• 2 a schematic sectional view of the in 1 embodiment shown, wherein the lid is in a second position; and
• 3 a schematic sectional view of a preferred embodiment of the pressure vessel according to the invention, in which several sample container systems, each according to the in the 1 and 2 preferred embodiment are provided.

1 and 2 show a sample container system 1 according to a preferred embodiment. The sample container system 1 has a sample container 2 with a sample container space 3 for holding a sample P. Optionally, a liquid F (eg a solvent) in which the sample P is dissolved, for example, can also be provided in the sample container space 3. The sample container space 3 can have the sample P and/or the liquid F, with the remaining volume of the sample container seam 3 being provided, for example, for a gas (e.g. a gas supplied to the sample container space 3 and/or a gas formed during a reaction taking place in the sample container space 3). can.

The sample container 2 has an edge 21 which defines an opening 22. The edge 21 and the opening 22 can have a circular shape. The sample P and/or the liquid F can be fed to the sample container space 3 via the opening 22. It is preferred if the sample container 2 has a side wall 23 which delimits the sample container space 3 and has the edge 21. The sample container 2 can have a bottom 24 from which the side wall 23 extends. The sample container 2 is preferably elongated and therefore preferably extends axially along a longitudinal axis. Seen in cross section (i.e. along a section transverse to the longitudinal axis of the sample container 2), the sample container 2 can have a (circular) round cross section. The sample container 2 is preferably a test tube.

The sample container system 1 also has a lid 4 which is designed to close the opening 22. The cover 4 has a plug-in section 41 with an outer surface 42. The lid can be inserted, in particular stuffed, into the sample container 2, namely via the opening 22, via the plug-in section 41. In this inserted state, at least part of the outer surface 42 is in contact with the sample container 2, in particular with an inside of the same. The plug-in section 41 preferably forms a press fit with the sample container 2. That is, in a state in which the plug portion 41 is plugged into the sample container 2, at least a part of the outer surface 42 is pressed or pressed against a wall portion of the sample container 2 due to an elastic restoring force of the plug portion 41. In other words, the outer surface 42 forms a pressing surface of the plug-in section 41 which interacts with the sample container 2. The plug-in section 41, when inserted into the sample container 2, is preferably held in a force-fitting manner, in particular pressed, between wall sections which, for example, have the side wall 23.

The cover 4 can also be moved axially relative to the sample container 2 via the plug-in section 41. In other words, the sample container 2 serves as a guide for the axial movement (ie displacement) of the plug-in section 41 relative to the sample container 2. Due to this suitability for axial movement, the lid 4 can in particular move away from the base 24 and towards the base 24 or, if present , moved away from the sample P and towards the sample P. The movement of the axial movement of the lid 4 preferably takes place along a movement axis which can be parallel to the longitudinal axis of the sample container 2. The plug-in section 41 is not limited to a specific shape. It is preferred if the plug-in section 41, as in the 1 and 2 shown by way of example, is at least partially cylindrical and therefore essentially has a (circular) round cross section. Alternatively or additionally, it can be provided that the plug-in section 41 has a conical shape.

The cover 4 further has a flange 43 which (viewed in a top view, which corresponds, for example, to a view in the direction of the axis (e.g. axis of symmetry) of the plug-in section 41) extends radially outwards from the plug-in section 41. Thus, for example, it can be provided that the flange 43 has a larger diameter than the plug-in section 41. When the plug-in section 41 is inserted into the sample container 2, the flange 43 is preferably flush with the edge 21. The flange 43 can have a diameter that essentially corresponds to the diameter of the sample container 2. In other embodiments, the flange 43 can also extend beyond the edge 21. Furthermore, the diameter of the flange 43 can be larger than the diameter of the sample container 2. The diameter of the sample container 2 is defined as the diameter which is an outer surface of the sample container 2, which faces away from the sample container space 3, and/or a radially outer end of the sample container 2 Rands 21 defined.

The flange 43 has a support side 44 over which the flange 43 and thus the cover 4 can rest on the edge 21. The support side 44 preferably has a support surface that is directed in the direction of the edge 21 and can contact it (flatly) when the lid 4 is inserted into the sample container 2. The flange 43 defines a maximum entry of the plug-in section 41 into the sample container 2. The flange 43 in particular prevents the lid 4 from entering too far into the sample container 2 and/or being arranged in its entirety below the edge 21, i.e. between the edge 21 and the bottom 24.

The lid 4 can have an underside 45, which preferably faces away from an upper side of the lid 4, which has the flange 43, for example. In particular, the plug-in section 41 can have the underside 45. In a state in which the plug-in section 41 is inserted into the sample container 2, the bottom 45 is provided so that it delimits the sample container space 3 (top). It can thus be provided that the sample container space 3 is delimited at the top by the underside 45, laterally by the side wall 23 and at the bottom by the bottom 24.

The cover 4 also has a recess 46, which first runs axially in the outer surface 42 of the plug-in section 41 and then runs radially outwards in the support side 44 of the flange 43. This means that the recess 46 extends in the outer surface 42 of the plug-in section 41 in the direction of the flange 43 and/or away from the underside 45. The recess 46 can extend away from the underside 45. The recess 46 extends to the flange 43, where it then merges into the support side 44 and then runs radially outwards. The recess 46 therefore runs at least along sections 461, 462, which adjoin one another and are preferably transverse (e.g. perpendicular) to one another. The first section 461 has the part of the recess 46 running in the outer surface 42 and the second section 462 has the part of the recess 46 running in the support side 44. It is preferred if a part of the recess 46 (for example the section 461) runs parallel to the longitudinal axis of the sample container 2 in the state in which the lid 4 is inserted into the sample container 2. The part of the recess 46 running in the support side 44 (i.e. the section 462) preferably runs transversely, particularly preferably perpendicular to the longitudinal axis of the sample container 2.

Via the recess 46, when the plug-in section 41 is inserted into the sample container 2 and the flange 43 rests with its support side 44 on the edge 21, the sample container space 3 can be fluidly connected to the environment U of the sample container system 1. The environment U has, for example, a reaction chamber and/or a gas located in the reaction chamber (which is not provided in the sample container space 3). The environment U can also have ambient air. In particular, there can be a pressure in the environment U that differs from the pressure that is present in the sample container space 3. The recess 46 can have an opening 47 through which a gas can flow into the recess 46 and thus into the sample container space 3. Alternatively or additionally, it can be provided that a gas from the sample container space 3 into the Recess 46 flow and is then released into the environment U via opening 47. For example, the recess 46 in the support side 44 can extend to the radially outer end of the flange 43, where it then forms the opening 47. However, this is not mandatory because, for example, the part of the recess 46 running in the support side 44 can also extend beyond the edge 21, but then not as far as the outer radial end of the flange 43, in order to provide an inlet from the environment U into the recess 46 and/or to effect an outlet from the recess 46 into the environment U.

The recess 46 may be at least partially formed in the form of a slot (or a groove or a groove or the like). At least the part of the recess 46 running in the outer surface 42 and/or in the support side 44 can be provided in the form of a slot. The recess 46 can be obtained by removing material from the outer surface 42 and/or the support side 44. Thus, the recess 46 can, for example, also be provided subsequently in a lid that does not yet have the recess 46.

The sample container system 1 and/or the lid 4 can have further elements, in particular elements that can interact with the fluid connection provided by the recess 46. For example, the sample container system 1 (for example above the lid 4) can have a cover disk (not shown) which is designed to prevent condensate from entering the recess 46, in particular in the form of drops falling due to gravity. For this purpose, the cover disk can be provided in such a way that it extends further radially outwards than the section of the recess 46 running in the support side 44. Seen in a side view, the cover disk preferably extends in such a way that at least the opening 47 is between it and the edge 21 is provided. Preferably, an outer end of the cover disk is provided further radially outward than the outlet opening 47.

The lid 4 is not limited to a specific material. The lid 4 can be made from just one material or from different materials. Preferably, the lid 4 is at least partially made of a plastic. The plastic may contain: PTFE, quartz and/or glass. For example, it can be provided that at least or only the plug-in section 41 is made of a plastic, for example a plastic that gives the plug-in section 41 a defined elasticity, which is preferably greater than the elasticity of the flange 43. A defined elasticity of the plug-in section 41 is particularly advantageous for inserting, in particular stuffing or pressing, the lid 4 into the sample container 2. In other embodiments, the lid 4 can also be made at least partially (or completely) from other materials such as cork.

The sample container system 1 can also have a stop element 5, which is arranged to limit a stroke of the lid 4 inserted into the sample container 2. The stop element 5 is preferably provided at a defined distance from the lid 4 when its support side 44 rests on the edge 21. The distance is preferably measured between the stop element 5 and an upper side of the lid 4, which has the flange 43, for example. In particular, the stop element 5 can be used to prevent the lid 4 from falling out of the sample container 2 or the lid 4 from jamming (for example with the sample container 2 and/or other parts, for example of a pressure container). In other words, the lid 4 continues to be inserted into the sample container 2 with its plug-in section 41 in a state in which it abuts against the stop element 5.

As the 1 and 2 As can be seen, the lid 4 can be moved axially (namely along the longitudinal axis of the sample container 2) by means of a stroke relative to the sample container 2 between a first position and a second position. The 1 shows the first position as an example. In the first position (when looking at the sample container 2 or the side wall 23 from the side) at least a part 48 of the recess 46 (which the first section 461 preferably has) is covered by the sample container 2, in particular by the side wall 23. As a result, a gas can essentially only leave the recess 46 via the opening 47. In other words, the recess 46 and the part of the sample container 2 that covers the recess 26 delimit a fluid line. A gas can then enter the fluid line thus formed (in the direction of the sample container space 3) and/or exit from it (in the direction of the environment U) via the opening 47. In the first position, the support side 44 preferably rests on the edge 21, so that there is preferably no gap between them with the exception of the recess 46 running in the support side 44 (including the optional opening 47). The first position preferably represents a (unpressurized) state in which there is no pressure gradient between the sample container space 3 and the environment U.

2 shows an example of the second position of the lid 4. In this position, the part 48 of the recess 46, which was covered by the sample container 2 in the first position, is out of the opening 22 moved out to protrude beyond the edge 21. This exposes part 48. The now exposed part 48 thus enlarges an outlet of the recess 46, whereby an increased gas flow can flow from the recess 46 into the environment U. In a preferred embodiment, as shown in the 1 and 2 is shown as an example, the outlet of the recess 46 is then formed at least by the opening 47 and the exposed part 48 of the recess 46. In the second position, the support side 44 is preferably spaced from the edge 21, whereby a gap is formed between the support side 44 and the edge 21, through which a fluid can flow from the recess 46 into the environment U. In the second position, part of the recess 46 is preferably still covered by the sample container 2 or the side wall 23.

The suitability of the lid 4 for the process from in 1 the first position shown in the 2 The second position shown is particularly advantageous for regulating a pressure (overpressure) in the sample container space 3. For example, if a reaction takes place in the sample container space 3, as a result of which a fluid (gas, liquid, etc.) develops and/or expands in the sample container space 3, the lid 4 is moved axially from the first position to the second position, whereby in particular an undesirable or at least undesirably rapid increase in pressure in the sample container space 3 is prevented. There is therefore no risk that excess pressure in the sample container space 3 will cause the sample container 2 to burst or damage other parts of the sample container system 2 such as the lid 4. At the same time, the axial movement (i.e. lifting) of the lid 4 into the second position increases the outlet (for example in the form of a slot) of the fluid connection provided by the recess 46 and thus automatically adapts it to the fluid development in the sample container space 3. In particular, the gases that develop in the sample container space 3 during the reaction can therefore quickly escape from the sample container space 3 into the environment U.

In 3 A preferred application of the sample container system 1 is shown, namely in a pressure vessel 100, which is, for example, a pressure reactor. The pressure container 100 therefore has the sample container system 1. The pressure container 100 is set up to accommodate one or more sample container systems 1 and to heat them (directly and/or indirectly) to trigger and/or promote chemical and/or physical pressure reactions on one or more samples P, for example by means of microwaves.

The pressure vessel 100 can be a (high-pressure) autoclave. The pressure vessel 100 preferably consists of a high-pressure-resistant material such as metal, preferably steel, particularly preferably a corrosion-resistant stainless steel alloy. The pressure vessel 100 is preferably designed in such a way that it can be used at pressures of up to at least 200 bar, preferably up to at least 500 bar, and at temperatures of up to and even above 300 ° C.

The pressure vessel 100 can have a reaction chamber or a pressure space 122 for triggering and/or promoting the chemical and/or physical pressure reactions on the samples P. The reaction chamber 122 is preferably a so-called fluid or gas space. The pressure vessel 100 can surround the reaction chamber 122 on all sides. The one or more sample container systems 1 are arranged in the reaction chamber 122 for sample treatment and can preferably be removed from it through an opening.

The pressure vessel 100 can have a (pot-shaped) lower part 120 and a lid 124 (also called “lid part”), which can be closed with one another and, when closed with one another, surround the reaction chamber 122 on all sides. The lid 124 closes the opening provided in the pressure vessel 100, i.e. the lower part 120 of the pressure vessel 100, for introducing and removing the sample P. By means of the lid 124, the pressure vessel 100 and/or the reaction chamber 122 can consequently be opened and closed. The pressure vessel 100 can have a fastening element 128, such as a clamp, which fastens the lid 124 to the lower part 120 in the closed state, in particular in such a way that they do not come apart from one another during a pressure reaction taking place in the reaction chamber 122.

The reaction chamber 122 can be designed to accommodate a liquid or base load. The liquid is preferably water, but can also be or have any other strong microwave-absorbing liquid. The liquid is intended in particular to heat or heat the sample P located in the at least one sample container system 1. This can be done, for example, by the sample P being at least partially surrounded by the liquid and a microwave generator heating the liquid by microwave absorption.

The pressure vessel 100 can also have a sample holder 108, with which one or more sample container systems 1 can be held in the reaction chamber 122. The sample holder 108 is preferably designed as a basket Taking several sample container systems 1 is formed. The sample holder 108 is in particular designed to place the at least one sample container system 1 into the reaction chamber 122 and out of it again via a rod-shaped handling structure (sample holder) 106, for example having a handle and / or flange area for preferably hanging attachment in the reaction chamber 122 refer to. The sample holder 108 can hang on the lid 124 and/or the further lid 142 described below.

The pressure vessel 100 may have a further lid (a so-called “liner”) 142, which is preferably made of plastic such as PTFE. The further cover 142 preferably serves as part of a lining in order to at least partially cover at least part of the cover 124, for example its back. The further lid 142 delimits the reaction chamber 122, preferably in such a way that a fluid located in the reaction chamber 122 is in contact with the further lid 142 and is therefore preferably not in contact with the lid 124. This prevents the cover 124 from being attacked in an undesirable manner by a fluid located in the reaction chamber 122.

In particular, to protect the inner wall of the lower part 120, a jacket 121, preferably made of plastic such as PTFE, can be provided in this, which at least partially delimits the reaction chamber 122. The jacket 121 therefore preferably forms an inner lining, in particular in the form of a container. The jacket 121 is preferably provided so that it, together with the further cover 142, surrounds the reaction chamber 122 on all sides. It is preferred if at least part of the further cover 142 (for example a flange area) is provided and/or clamped between the jacket 121 and the cover 124.

The pressure vessel 100 can have a fluid line 114 via which a charging gas can enter the reaction chamber 122 in order to increase a pressure in it (pressure charging). The fluid line 114 preferably extends through the cover 124 and/or through the further cover 142.

The 3 shows that in relation to the 1 and 2 The described function of the sample container system 1 can be used to regulate a pressure in the sample container space 3 in the pressure container 100. In particular, it is not necessary for the pressure container 100 to have means that regulate a pressure in the sample container space 3. Rather, the pressure prevailing in the sample container space 3 can simply be regulated exclusively via the design of the lid 4. This simplifies pressure regulation without having to adjust the pressure vessel 100.

In particular, a gas flowing from the fluid line 114 can flow into the sample container space 3 via the fluidic connection, which is provided at least through the recess 46 of the sample container system 1. Furthermore, a gas (for example a reaction gas that arises during a reaction taking place in the sample container space 3) can escape into the reaction chamber 122 via the fluidic connection of the sample container system 1 and can then be discharged from there from the pressure container 100, for example via a discharge line (not shown) that the pressure vessel 100 has.

If the sample container system 1 is provided in the pressure container 100, the stop element 5 can be formed by a part of the pressure container 100. For example, the cover 124 or the further cover 142 can have or form the stop element 5. For example, the stop element 5 can be formed integrally with the cover 124 or the further cover 142. Alternatively or additionally, it can be provided that the sample holder 108 and/or the handling structure 106 has the stop element 5. For example, the stop element 5 may be detachably provided on or integral with the handling structure 106.

The invention is not limited to the features described above; in particular, the features described above can be combined with one another in any way.

Claims (13)

Sample container system (1) for use in a pressure container (100), comprising: a sample container (2) with - a sample container space (3) for receiving a sample (P) and - an edge (21) which defines an opening (22); and a lid (4) for closing the opening (22), the lid (4) having: - a plug-in section (41) which can be inserted into the sample container (2) via the opening (22) and via which the lid ( 4) is axially movable relative to the sample container (2), - a flange (43) which extends radially outwards from the plug-in section (41) and, when the plug-in section (41) is inserted into the sample container (2), with a support side (44) can rest on the edge (21), and - a recess (46) in an outer surface (42) of the plug-in section (41) runs axially and then radially outwards in the support side (44) of the flange, so that when the plug-in section (41) is inserted into the sample container (2) and the flange (43) is connected to the support side ( 44) rests on the edge (21), the sample container space (3) is fluidly connected to the environment (U) of the sample container system (1) via the recess (46). Sample container system (1). Claim 1 , wherein, when the plug-in section (41) is inserted into the sample container (2), the lid (4) is axially movable by stroke relative to the sample container (2) at least between a first position and a second position, at least a part ( 48) the recess (46) is covered by the sample container (2) in the first position and protrudes beyond the edge (21) in the second position and is thereby exposed. Sample container system (1). Claim 1 or 2 , wherein the sample container (2) extends axially along a longitudinal axis, and wherein, when the plug-in section (41) is inserted into the sample container (2), the part of the recess (46) running in the outer surface (42) is at least partially parallel to the longitudinal axis runs. Sample container system (1) according to one of the preceding claims, wherein the recess (46) is slot-shaped. Sample container system (1) according to one of the preceding claims, wherein the plug-in section (41) has a bottom (45) which, when the plug-in section (41) is inserted into the sample container (2), delimits the sample container space (3), the recess (46) extends away from the underside (45) and/or starting from the underside (45). Sample container system (1) according to one of the preceding claims, wherein the plug-in section (41) is cylindrical and/or conical, and/or wherein the plug-in section (41) has a round, preferably circular cross-section. Sample container system (1) according to one of the preceding claims, wherein the lid (4) is at least partially made of plastic. Sample container system (1). Claim 7 , where the plastic comprises: PTFE, quartz and/or glass. Sample container system (1) according to one of the preceding claims, wherein, when the plug-in section (41) is inserted into the sample container (2) and the support side (44) rests on the edge (21), the flange (43) is flush with the edge ( 21) is. Sample container system (1) according to one of the preceding claims, wherein, when the plug-in section (41) is inserted into the sample container (2) and the support side (44) rests on the edge (21), the part running in the support side (44). Recess (46) protrudes beyond the edge (21). Sample container system (1) according to one of the preceding claims, further comprising a cover element which is designed to prevent condensate from entering, in particular in the form of drops, into the recess (46), the cover element preferably being a lid or a cover disk. Sample container system (1) according to one of the preceding claims, further comprising a stop element (5) which is arranged to limit a stroke of the lid (4) inserted into the sample container (2), in particular to prevent the lid (4) from falling out of the To prevent sample container (2). Pressure container (100) comprising a sample container system (1) according to one of the preceding claims.