DE202012008894U1 - Reaction tank system with rotor - Google Patents

Abstract

Reaction tank system (1) comprising:
Reaction container (2) for receiving samples, a rotor (3) for reactions, in particular for pressure reactions, comprising:
An upper part (4) and a lower part (5),
Protective sheaths (6) for detachably receiving the reaction containers (2), the protective sheaths (6) extending between the upper part (4) and the lower part (5), and the protective sheaths (6) being fixedly connected to the lower part (5) are and these together form a rotor body (GK),
the upper part (4) having receiving openings (7) via which the reaction containers (2) are detachably inserted into the protective sheaths (6),
characterized in that
the upper part (4) is detachably connected to the rotor main body (GK), and
the reaction containers (2) are detachably received in the receiving openings (7) of the upper part (4) in such a way that they can be moved by means of the upper part (4) to insert the reaction containers (2) into the protective jackets (6) and remove them therefrom ,

Description

The present invention relates to a reaction vessel system with reaction vessels for receiving samples and a rotor for reactions, in particular for pressure reactions with a top and a base and extending therefrom protective shells for releasably receiving the reaction vessel. The invention further relates to a rotor of the aforementioned type and a reaction system with the rotor.

Rotors of the aforementioned type are known from the prior art. These generally have an upper part and a lower part, between which protective sheaths for releasably receiving reaction containers extend. The protective jackets are firmly connected to the upper part and the lower part and together form a rotor body. In the upper part receiving openings are provided, are releasably used on the reaction container in the protective jackets.

Rotors of the aforementioned construction are usually rotatably mounted in a reaction space. To remove the samples, the reaction vessels must be removed individually from the rotor. This is very time-consuming and involves the risk of confusion of individual samples and increases the risk of damage or contamination of the reaction vessel or the sample by the large number of individual steps. The reaction containers are usually placed on a table or transferred to a sample holder (eg rectangular holder), for which a large contact surface is necessary. Due to their small footprint, the reaction vessels are unstable and can easily fall over, putting the laboratory staff at risk.

Alternatively, it is also known to remove the entire rotor together with the reaction vessels from the reaction space. In this case, the rotor is no longer available during handling with the reaction containers for a further reaction, so that the reaction space can not be used continuously or possibly additional rotors are to be provided, which on the one hand requires a larger space and on the other is costly.

It is thus an object of the invention to provide a reaction container system and a rotor as well as a corresponding reaction system, which offer a high level of operating comfort and are also simple in their construction and space-saving.

This object is solved by the subject matter of the independent claims. The dependent claims further form the central idea of the invention in a particularly advantageous manner.

According to a first aspect, the invention relates to a reaction vessel system comprising reaction vessels (in the context of the invention this is always understood to mean at least one reaction vessel) for receiving samples and a rotor for reactions, in particular for pressure reactions. The rotor has an upper part and a lower part as well as protective sheaths (in the context of the invention, this is always understood to mean at least one protective sheath) for releasably receiving the (or the) reaction container (s). The protective coats extend between the upper part and the lower part and are firmly connected to the lower part. The lower part and the protective shells firmly connected to the lower part together form a rotor main body. The upper part has receiving openings (in the context of the invention, this is always understood to mean at least one receiving opening), via which the reaction containers are detachably inserted into the protective jackets. The upper part is detachably connected to the rotor base body. The reaction containers are detachably received in the receiving openings of the upper part in such a way that they can be moved by means of the upper part in order to insert the reaction containers into the protective jackets and remove them therefrom.

By means of the above-mentioned reaction container system, it is possible to remove all reaction containers (automatically) from the protective sheaths or the rotor main body at the same time or to put them into them. Thus, all of the reaction vessels can be lifted together by means of a single handling step, and preferably with a single grip with the top, while the rotor body can remain at its original position (eg within a reaction chamber). In this way, the reaction vessels can be removed in a user-friendly manner quickly and easily, for example, to quickly place them together in / under a fume hood or to simultaneously convey all reaction vessels to a water bath for rapid cooling. Since the rotor base body can remain at its original location, it can be used directly after removal of an upper part together with the reaction containers received therein for a new reaction step in which new samples are moved into reaction containers together by means of a shell in the protective shells of the rotor body. As a result of the simple handling of several or all reaction containers at the same time, the sample throughput can consequently be increased significantly.

The reaction container system may further comprise a sample holder device, on which the upper part can preferably be placed together with the reaction containers, which were previously removed from the rotor base body. The upper part is for this purpose preferably designed such that it is optionally placeable on the rotor body or the sample holder device. The upper part thus serves not only as a rotor upper part together with the rotor main body, but at the same time as a sample holder which can be placed on the sample holder device. In this way, the reaction vessel can be sorted into a fume hood, opened according to a reaction sequence before opening, individually opened and transferred or distributed for further analytical procedures. A chaotic shutdown in the trigger, as was the case with a separate removal of the individual reaction containers according to the prior art, is thus avoided. Likewise, a slight overturning of the reaction vessel by safely receiving it in the shell during the entire handling is avoided, while only a small working surface is necessary for the handling of the reaction vessel. A further advantage is that the sample holder device together with the upper part and the reaction containers accommodated therein can be placed together in a water bath, whereby an extremely fast cooling of the samples is achieved in the reaction vessels, so that the sample throughput continues due to the ease of use and rapid cooling can be increased.

In order to avoid a positional confusion, the upper part preferably has first coding means, which correspond with coding elements of the rotor base body for unambiguous alignment of the upper part on the rotor base body. The coding means may comprise a first profiling, such as a depression or an opening, and the coding elements may comprise a second profiling, such as a protrusion or an exposed element. In the case of the upper part connected to the rotor base body or the sample holder device, the coding means and coding elements formed in this way thus correspond with one another easily and securely. Preferably, coding means and coding elements interlock; for example in the form of a tongue and groove connection.

The sample holder device may have a base and associated holding elements. The upper part can be placed on these holding elements in order to place the upper part preferably together with the reaction containers on the sample holder device. The holding elements may also have coding elements, which correspond to second coding means of the upper part for unambiguous alignment of the upper part on the sample holder device. The second coding means and the coding elements of the holding elements are preferably designed in a comparable manner as the first coding means and the coding elements of the rotor main body. In a particularly preferred embodiment, the first coding means and the second coding means form the same coding means, so that one and the same coding means of the upper part can cooperate or correspond with both the coding elements of the rotor base body and with the coding elements of the holding element.

The rotor base body may further comprise a central part, which is provided between the protective jackets and the upper part and fixedly connected to the protective jackets. The middle part preferably has insertion openings corresponding to the receiving openings of the upper part for the reaction containers; in other words, the receiving openings of the upper part and the insertion opening of the middle part are aligned with each other and these in turn are aligned with at least a part and preferably with all protective sheaths or protective sheath openings to introduce corresponding reaction vessel through the receiving openings and insertion openings in the protective shells. Preferably, the middle part has the coding elements of the rotor main body.

The upper part preferably has a coding for the receiving openings. For this purpose, an individual code is particularly preferably associated with each receiving opening. In particular, the coding may have a numbering, wherein, for example, each receiving opening is assigned its own number, preferably a continuing number. Since the upper part, which can be handled together with the reaction containers, is provided with the coding, it automatically moves with the upper part and the reaction containers when they are removed, for example, from the rotor main body and placed on a sample holder device. In this way, swapping the samples can be safely avoided. Furthermore, this construction also saves a lot of time in addition to a lot of time.

According to a second aspect, the invention relates to a rotor comprising an upper part and a lower part and protective sheaths for detachably receiving reaction containers, wherein the protective sheaths extend between the upper part and the lower part, and wherein the protective shells are firmly connected to the lower part and these together form a rotor main body form. The upper part has receiving openings, via which the reaction containers can be detachably inserted into the protective jackets. The upper part is detachably connected to the rotor base body. The receiving openings are formed such that detachably received in the receiving openings reaction container by means of the upper part are movable to insert the reaction container in the protective coats and to remove from these.

The advantages with respect to the rotor arise in the same way as the advantages of the reaction container system according to the first aspect of the invention. With regard to further features and configurations of the rotor, reference is also made to the above statements.

According to a third aspect, the invention relates to a reaction system comprising a closable reaction space in which a rotor according to the invention is arranged, and a shaft connected to the rotor for driving the rotor. The reaction system further includes a heat source for heating samples in the reaction space, more specifically in reaction vessels in the reaction space. Such a heat source can be, for example, a microwave radiation source for coupling microwaves into the reaction space.

Further embodiments and advantages of the invention will be described below with reference to an embodiment in conjunction with the figures of the accompanying drawings.

1 shows a reaction vessel system with reaction vessels and a rotor according to the invention,

2a shows a reaction tank system according to 1 and a sample holder device,

2 B shows a rotor body and a placed on a sample holder device upper part with reaction vessels after transferring the upper part of the sample holder device,

2c shows the sample holder device according to 2 B , and

3 shows a reaction container system and a sample holder device according to the invention.

1 to 3 show a reaction tank system 1 according to the invention. The reaction tank system 1 has at least one, preferably several (eg. 34 or 44 ) Reaction vessel 2 for receiving samples. Such reaction vessel 2 are known in principle from the prior art and are preferably made of materials with properties selected according to the reaction with respect to temperature, pressure and sample to be used; For example, they are made of PTFE. For pressure reactions are the reaction vessels 2 preferably formed as a pressure vessel and preferably have an automatic pressure relief valve made of PTFE. The reaction vessels 2 are also preferably chosen so that they fit common analytical scales.

The reaction tank system 1 also has a rotor 3 for reactions, especially for pressure reactions. The rotor 3 alone is also the subject of the invention. The rotor 3 has preferably with respect to its axis of rotation R a rotationally symmetrical shape. For example, as shown in the figures, it may have a substantially cylindrical shape.

The rotor 3 has a top 4 and a lower part 5 which are spaced apart, preferably axially spaced from each other with respect to the axis of rotation R. Both the top 4 as well as the lower part 5 are preferably made of a microwave-transparent or microwave-reflecting material (for example metal, aluminum).

Furthermore, the rotor has 3 at least one or more protective coats 6 for releasably receiving the reaction vessel 2 on. The protective coats 6 preferably have an inner contour, which the outer contour of the reaction vessel 2 essentially corresponds; particularly preferably, the reaction vessels are 2 when in the protective coats 6 or in each case in a protective jacket 6 are used, at least partially or preferably over the entire surface to each other. The protective coats 6 extend between the shell 4 and the lower part 5 and are preferably substantially parallel to the axis of rotation R of the rotor 3 aligned. Preferably, the protective jackets 6 with respect to the axis of rotation R over the circumference of the rotor 3 seen distributed, preferably arranged evenly distributed. Depending on the device type, for example 10 (see. 3 ) 34 (see. 1 and 2 ) or 44 reaction vessel 2 or appropriate protective coats 6 each rotor 3 be provided. The number of protective coats 6 however, is not limited by the invention. The number of reaction vessels 2 is preferably on the number of protective coats 6 therefore, they are usually identical if all protective coats 6 each with a reaction tank 2 are occupied. The protective coats 6 are preferably on a circular path about the axis of rotation R of the rotor 3 arranged with a constant radius. However, it is also conceivable that the protective coats 6 with respect to the axis of rotation R are arranged on different circular paths, each with a different radial distance from the axis of rotation R; for example, on two coaxial rings, as exemplified in 1 is shown. The protective coats 6 are with the lower part 5 firmly connected, for example, integrally formed with each other or screwed together, welded or the like. The protective coats 6 as well as the lower part 5 together form a rotor body GK.

For pressure reactions are the protective jackets 6 preferably designed as pressure jackets. Such pressure jackets are preferably made of a ceramic Fabric made, which allows a particularly fast cooling. The printing coats or protective coats 6 preferably have a material resistance of over 300 ° C and 100bar. The use of particularly lightweight materials of the rotor body GK and the upper part 4 leads to a weight reduction of the rotor 3 in comparison to known devices and thus to a simplified handling of these parts.

The top 4 has at least one or more (preferably according to the number of protective coats 6 ) Receiving openings 7 on, over which the reaction vessels 2 in the protective coats 6 are releasably used or used. The receiving openings 7 Consequently, they are preferably aligned at least with one part, but more preferably with all (the upper part 4 facing) protective shell openings 8th ,

The top 4 is detachably connected to the rotor body GK, wherein the upper part 4 Preferably, at least during a sample reaction with the rotor body GK, for example. By means of screws or quick fasteners or the like is securely fixed. The top 4 preferably has first coding means, which with a coding element 18 of the rotor main body GK for clear alignment of the upper part 4 on the rotor body GK correspond. For this purpose, the coding means preferably have a first profiling and the coding elements 18 a second profiling, which when placed on the rotor body GK upper part 4 correspond with each other and particularly preferably interlock; for example in the form of a tongue and groove connection or by means of another connection technology, in particular a positive or non-positive connection. For this purpose, the first profiling, for example, have a depression or an opening, the second profiling, for example, a corresponding survey or an exposed element (see. 18 in 2 B and 3 ) that correspond or intermesh with each other. By using the coding means and the coding elements 18 will ensure that appropriate receiving openings 7 of the top 4 with a corresponding upper part 4 always with the (same) protective sheath openings 8th aligned to insert the reaction vessel 2 through the receiving openings 7 in the protective coats 6 safe, easy and preferably position-defined to allow.

Both the coding means and the coding elements 18 can in the plan view, ie in the direction of the rotation axis R, evenly distributed - so for example in the form of an equilateral triangle or otherwise - or unevenly distributed - so for example in the form of an isosceles triangle or other orderly or disorderly manner - be arranged. In the latter case, due to a clear assignment of the coding means to the coding elements 18 a positional confusion of the upper part 4 be avoided with respect to the rotor body GK. For example, when viewed in plan view, the coding means or coding elements 18 connecting triangle two identical angles (for example 125 °) and an angle deviating therefrom (eg 110 °) include, so that a clear assignment of the coding means with coding elements 18 is possible.

As in particular the 2 B and 3 can be seen, the rotor body GK can also have a central part 9 have, which - as in 1 or 2a can be seen - between the protective coats 6 and the top 4 is provided when the upper part 4 placed on the rotor body GK. The middle part 9 is, as well as the lower part 5 , firmly with the protective coats 6 connected, in which case the lower part 5 , the middle part 9 as well as the protective coats 6 form a coherent body - the rotor body GK -. The middle part 9 preferably has with the receiving openings 7 of the top 4 aligned insertion openings 10 for the reaction vessels 2 on. Preferably, the middle part 9 the coding element 18 of the rotor base body GK, thus has correspondingly uniform or unevenly distributed profilings, which with corresponding profiles of the upper part 4 for clear alignment of the upper part 4 on the rotor body GK correspond, preferably intermesh.

The reaction vessels 2 are so detachable in the receiving openings 7 of the top 4 recorded that by means of the shell 4 are so movable to the reaction vessel 2 in the protective coats 6 to insert and remove from these. In other words, the receiving openings 7 designed such that releasably in the receiving openings 7 recorded reaction vessel 2 by means of the shell 4 are so movable to the reaction vessel 2 in the protective coats 6 to insert and remove from these. It is thus possible to use all the reaction vessels 2 only by handling the upper part 4 move together and thus easy to use and easy reaction containers 2 in the protective coats 6 introduce or remove from the rotor body GK. Thus, on the one hand, the time required to remove the reaction vessel 2 from the rotor 3 be significantly reduced while at the same workplace - for example, to turn off the reaction vessel 2 in the deduction - can be saved. On the other hand, the rotor main body GK remains available for further samples, for example in a reaction space, so that, for example, after a simple, simultaneous insertion of reaction vessels 2 by means of another shell 4 a new reaction can be performed immediately after taking treated samples.

So that in the receiving openings 7 recorded reaction vessel 2 by means of the shell 4 are safely movable, assign the reaction vessel 2 for example, a preferably cylindrical body 16 on, which has a diameter which is less than or equal to the diameter of the receiving openings 7 is. At its upper end, the reaction vessels 2 furthermore a head area 17 on, for example, a closable lid of the reaction vessel 2 can form, which has a diameter which is greater than the diameter of the receiving openings 7 is. In this way, the reaction vessels 2 with their basic samples having the samples 16 through the receiving openings 7 and optionally the insertion openings 10 in the protective coats 6 be used while the reaction vessels 2 at least when handling by means of the upper part 4 with her widened head area 17 on the top 4 such as in the 2 B and 2c is shown. However, other embodiments are conceivable to make it the reaction vessels 2 to allow through the receiving opening 7 be introduced into the protective coats and at the same time in a handling of the upper part 4 to be carried along with this. For example, corresponding latching elements can be provided, which slipping out of the reaction vessel 2 from the top 4 through the receiving opening 7 safely avoids. It is also conceivable that the reaction vessel 2 by means of a magnetic holder in the upper part 4 are included and thus in the handling of the upper part 4 be carried along with this.

Like that 2a to 2c and 3 can be seen, has the reaction tank system 1 further preferably a sample holder device 11 on. The sample holder device 11 preferably has a base 12 and associated holding elements 13 on. The latter preferably extend in the same direction in a pin-like manner from the base 12 path. Like that 2 B and 2c it can be seen, is the top 4 on the holding elements 13 placed. For this purpose, according to a preferred embodiment, the upper part 4 designed such that it - preferably together with the reaction vessels 2 - Optionally on the rotor body GK (see. 1 and 2a ) or the sample holder device 11 (see. 2 B and 2c ) is placeable.

According to a preferred embodiment, have the holding elements for this purpose 13 coding elements 14 on, which with second coding means of the shell 4 for clear alignment of the upper part 4 on the sample holder device 11 correspond. The second coding means of the shell 4 as well as the coding elements 14 the holding elements 13 are here preferably comparable to the first coding means of the upper part 4 as well as the coding elements 18 formed of the rotor body GK; Thus, they preferably have corresponding profiles and are arranged corresponding to each other, preferably to a unique orientation of the upper part 4 on the sample holder device 11 to enable. As 2a and 3 can be seen, the coding elements 14 the holding elements 13 for example in the form of coding pins, which are in the second coding means of the upper part 4 - For example, in the form of corresponding openings or recesses - can be introduced or intervene.

Both the first and the second coding means as well as the coding elements 18 . 14 of the rotor main body GK and the sample holder device 11 can in a plan view, ie in the direction of the axis of rotation R of the rotor 3 seen evenly or unevenly (around the circumference of the rotor 3 ) distributed (for example in the form of an equilateral or isosceles triangle) distributed. Preferably, there are at least three coding means or coding elements 18 . 14 depending on the corresponding component. According to a particularly preferred embodiment, the first coding means and the second coding means are the same coding means, so that one and the same coding means of the upper part 4 both with the coding elements 18 of the rotor body GK and with the coding elements 14 the sample holder device 11 for clear alignment of the upper part 4 on the rotor body GK or the sample holder device 11 are placeable.

Because the top part 4 preferably both on the rotor base body GK and the sample holder device 11 also together with the reaction vessels 2 placeable, all reaction vessels can 2 in a simple way at the same time from the protective coats 6 taken out and directly as a sample holder on the sample holder device 11 to be placed. As the sample holder device 11 preferably corresponding coding devices (coding elements 14 ), a safe transport for further sample preparation steps is ensured. The reaction vessels 2 can thus be easily sorted and safely sorted prior to opening in a fume hood, individually opened and transferred or distributed for further analytical procedures. Also, the reaction vessels can 2 by means of the sample holder device 11 be handled in a simple manner and, for example, placed in a water bath for very fast cooling, which in turn significantly increases the sample throughput.

The top 4 can also be a coding 15 for the receiving openings 7 preferably, each receiving opening 7 an individual code is assigned. As can be seen, for example, the figures, the coding 15 preferably have a numbering, the each receiving opening 7 assigns its own number, preferably a consecutive number series. As for the handling of the upper part 4 which the coding 15 has, at the same time the reaction vessel 2 be moved, the sample coding remains in the handling of the reaction vessel 2 by means of the shell 4 obtained automatically, causing a confusion of samples or reaction containers 2 excluded with the respective samples.

The position coding by means of the coding means and coding elements 18 ensures exact positioning of the rotor components to each other and the sample coding by means of coding 15 of the top 4 ensures an exact positioning of the reaction vessel 2 regarding the upper part 4 , In particular, the latter in turn allows accurate temperature monitoring and pressure control of each individual reaction vessel 2 , The data of the coding 15 accurately assigned associated reaction vessels 2 can be stored, for example, in a sample treatment software for (partially) automatic sample treatment or for (semi-) automatic sample handling and retrieved and used during the entire handling or reaction sequence, so that the samples can always be safely assigned.

As previously mentioned, according to a preferred embodiment, the rotor 3 or the reaction vessel system 1 also be designed for a fully or partially automated process. For this purpose, in the upper part 4 For example, be provided engaging openings, in which engage a corresponding handling element of a robot arm and the upper part 4 can fix. By means of such a handling device, the upper part 4 together with the reaction vessels 2 be driven from the rotor body GK, while the rotor body GK, for example by means of a shaft on which the rotor body GK is fixed, is held.

The invention is further directed to a reaction system, in particular a pressure reaction system. This reaction system has a closable reaction space in which a rotor 3 is arranged according to the invention. Furthermore, the reaction system has one with the rotor 3 or at least with the rotor body GK connected shaft for driving the rotor 3 on. Further, the reaction system may include a heat source for heating samples in the reaction space. The heat source can be, for example, a microwave radiation source for coupling microwaves into the reaction space. In this case, the reaction space is a microwave space.

The reaction tank system 1 or the reaction system can be used in all conceivable routine digestion processes such as soil, sewage sludge and food analysis, etc.

The following is a method for handling reaction vessels 2 described.

A rotor 3 is provided, preferably in a reaction space (eg microwave space) of a reaction system, wherein the rotor 3 is preferably connected by means of a shaft for driving the rotor or is. The rotor 3 has the features of the above-described rotor according to the invention 3 on. The upper part which is detachably connected to or connected to the rotor body GK 4 has receiving openings 7 on, over which the reaction vessels 2 in the protective coats 6 be used detachably. The insertion of the reaction vessel 2 on the one hand, first into the receiving openings 7 of the top 4 happen, which is not yet placed on the rotor body GK. In this case, and more preferably, basically, the reaction vessels 2 in the receiving openings 7 held so releasably that they together with the upper part 4 are movable. By placing the upper part 4 on the rotor body GK (see arrows P3 in 3 ) become the reaction vessels 2 automatically retracted into the protective jackets (see arrow P4 in 3 ). Alternatively, first, the top 4 placed on the rotor body GK and the reaction vessel 2 only then through the receiving openings 7 in the protective coats 6 be used. The reaction vessels 2 stay with the receiving openings 7 so connected or incorporated in that they in a handling of the upper part 4 be moved along with this. In the protective coats 6 The reaction vessels snap in place 2 preferably in the lower part 5 a, which for this purpose a corresponding locking device at the bottom of the protective coats 6 can have.

Subsequently, a reaction, preferably a pressure reaction, is carried out. This is the rotor 3 either already arranged in a reaction space or is used in this; preferably such that it is or is connected to a shaft. The reaction space is closed before the reaction - for example by means of a door.

After the (pressure) reaction, the reaction vessels become 2 from the protective coats 6 taken. This is the top part 4 lifted from the rotor body GK, which due to the inclusion of the reaction vessel 2 in the receiving openings 7 or the upper part 4 these automatically moved and thus from the protective coats 6 be removed.

Preferably, the upper part 4 - together with the reaction vessels 2 - Then on a sample holder device 11 placed (see arrow P1 in 2 B ). Before placing the shell 4 on the sample holder device 11 or together with the sample holder device 11 can those with the shell 4 together moving reaction vessel 2 placed in a water bath for rapid cooling. Likewise, the reaction vessels 2 together, preferably on the sample holder device 11 to be put in a deduction. In principle, a (pre-) cooling in the reaction space itself is conceivable; for example in the form of air cooling.

For clear alignment of the upper part 4 on the rotor body GK or the sample holder device 11 has the top 4 preferably coding means and the rotor body GK and the sample holder device 11 preferably coding elements 18 . 14 on, which correspond with each other; preferably intermesh. For this purpose, the coding means and the coding elements 14 . 18 mutually corresponding profiles, which are particularly preferably arranged such that they have a clear orientation of the upper part 4 to the rotor body GK or the sample holder device 11 enable.

Subsequently (ie after the reaction or a possible cooling), the reaction vessel 2 - preferably in a fume hood - individually opened and transferred or distributed for further analytical procedures. For this purpose, the reaction vessel 2 then also from the top 4 , which is preferably in the sample holder device 11 is taken individually (see arrows P2 in 2c ). By means of a coding 15 which are on the top 4 is provided and thus during handling of the reaction vessel 2 by means of the shell 4 automatically mitwandert with this, can be a mistake of the reaction container 2 or the samples taken therein are excluded.

The invention is not limited to the aforementioned embodiments, as long as it is encompassed by the subject matter of the claims. In particular, the number and design (eg. Shape and dimensions) of the protective jackets 6 , the reaction vessel 2 , the coding means as well as the coding elements and holding elements are not limited by the invention. Furthermore, the invention is not limited to specific materials of the individual elements, as long as they are suitable for the corresponding reaction.

Claims (17)

Reaction tank system ( 1 ) comprising: reaction vessels ( 2 ) for receiving samples, a rotor ( 3 ) for reactions, in particular for pressure reactions, comprising: an upper part ( 4 ) and a lower part ( 5 ), • protective coats ( 6 ) for releasably receiving the reaction vessels ( 2 ), the protective coats ( 6 ) between the upper part ( 4 ) and the lower part ( 5 ) and the protective sheaths ( 6 ) with the lower part ( 5 ) are firmly connected and together form a rotor body (GK), wherein the upper part ( 4 ) Receiving openings ( 7 ), via which the reaction vessels ( 2 ) in the protective coats ( 6 ) are detachably inserted, characterized in that the upper part ( 4 ) releasably connected to the rotor body (GK), and the reaction vessels ( 2 ) detachably in the receiving openings ( 7 ) of the upper part ( 4 ) are received by means of the upper part ( 4 ) are movable to the reaction vessel ( 2 ) in the protective coats ( 6 ) and to remove from these. Reaction tank system ( 1 ) according to claim 1, further comprising a sample holder device ( 11 ), the top ( 4 ) is designed such that it preferably together with the reaction vessels ( 2 ) optionally on the rotor body (GK) or the sample holder device ( 11 ) is placeable. Reaction tank system ( 1 ) according to claim 1 or 2, wherein the upper part ( 4 ) has first coding means, which with coding elements ( 18 ) of the rotor body (GK) for unambiguous alignment of the upper part ( 4 ) on the rotor body (GK). Reaction tank system ( 1 ) according to claim 2 or 3, wherein the sample holder device ( 11 ) One Base ( 12 ) and associated holding elements ( 13 ), and the upper part ( 4 ) on the holding elements ( 13 ) can be placed. Reaction tank system ( 1 ) according to claim 4, wherein the retaining elements ( 13 ) Coding elements ( 14 ), which with second coding means of the upper part ( 4 ) for the clear alignment of the upper part ( 4 ) on the sample holder device ( 11 ) correspond. Reaction tank system ( 1 ) according to claim 3 and 5, wherein the first coding means and the second coding means of the upper part ( 4 ) are the same coding means. Reaction tank system ( 1 ) according to one of claims 3 to 6, wherein the coding means a first profiling, such as a depression or an opening, and the coding elements ( 18 . 14 ) have a second profiling, such as a survey or an exposed element, which in with the Rotorgrundkörper (GK) or the sample holder device ( 11 ) connected top ( 4 ) correspond to each other, preferably intermesh. Reaction tank system ( 1 ) according to one of the preceding claims, wherein the rotor main body (GK) further comprises a central part ( 9 ), which between the protective coats ( 6 ) and the upper part ( 4 ) and fixed with the protective coats ( 6 ), the middle part ( 9 ) preferably with the receiving openings ( 7 ) of the upper part ( 4 ) aligned insertion openings ( 10 ) for the reaction vessels ( 2 ), and wherein the middle part ( 9 ) preferably the coding elements ( 18 ) of the rotor base body (GK). Reaction tank system ( 1 ) according to one of the preceding claims, wherein the upper part ( 4 ) a coding ( 15 ) for the receiving openings ( 7 ), wherein preferably each receiving opening ( 7 ) an individual code is assigned, the coding ( 15 ) preferably has a numbering. Reaction tank system ( 1 ) according to one of the preceding claims, wherein the protective sheaths ( 6 ) Pressure jackets and reaction vessels ( 2 ) Pressure vessels are. Rotor ( 3 ) comprising: a top ( 4 ) and a lower part ( 5 ), Protective coats ( 6 ) for releasably receiving reaction vessels ( 2 ), the protective coats ( 6 ) between the upper part ( 4 ) and the lower part ( 5 ) and the protective sheaths ( 6 ) with the lower part ( 5 ) are firmly connected and together form a rotor body (GK), wherein the upper part ( 4 ) Receiving openings ( 7 ), via which the reaction vessels ( 2 ) in the protective coats ( 6 ) are detachably insertable, characterized in that the upper part ( 4 ) is detachably connected to the rotor main body (GK), and the receiving openings ( 7 ) are designed such that releasably in the receiving openings ( 7 ) received reaction vessel ( 2 ) by means of the upper part ( 4 ) are movable to the reaction vessel ( 2 ) in the protective coats ( 6 ) and to remove from these. Rotor ( 3 ) according to claim 10, wherein the upper part ( 4 ) a coding ( 15 ) for the receiving openings ( 7 ), wherein preferably each receiving opening ( 7 ) an individual code is assigned, the coding ( 15 ) preferably has a numbering. Rotor ( 3 ) according to claim 10 or 11, wherein the upper part ( 4 ) has first coding means, which with coding elements ( 18 ) of the rotor body (GK) for unambiguous alignment of the upper part ( 4 ) on the rotor body (GK). Rotor ( 3 ) according to claim 12, wherein the coding means comprise a first profiling, such as a depression or an opening, and the coding elements ( 18 ) have a second profiling, such as a protrusion or an exposed element, which, when the upper part is connected ( 4 ) with the rotor base body (GK) with each other, preferably intermesh. Rotor ( 3 ) according to one of claims 10 to 13, wherein the rotor main body (GK) further comprises a central part ( 9 ), which between the protective coats ( 6 ) and the upper part ( 4 ) and fixed with the protective coats ( 6 ), the middle part ( 9 ) preferably with the receiving openings ( 7 ) of the upper part ( 4 ) aligned insertion openings ( 10 ) for the reaction vessels ( 2 ), and wherein the middle part ( 9 ) preferably the coding element ( 18 ) of the rotor base body (GK). Reaction system comprising a closable reaction space in which a rotor ( 3 ) according to claims 11 to 15, as well as one with the rotor ( 3 ) connected shaft for driving the rotor ( 3 ). A reaction system according to claim 16, further comprising a heat source for heating samples in the reaction space, such as a microwave radiation source for coupling microwaves into the reaction space.

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