DE4114525A1 - DEVICE FOR TRIGGERING AND / OR PROMOTING CHEMICAL AND / OR PHYSICAL PRESSURE REACTIONS - Google Patents

Description

The invention relates to a device for triggering and / or conveying chemical and / or physical Pressure reactions according to the preamble of claim 1.

From DE-OS 38 18 697 it is known for chemical and physical pressure reactions conventional microwaves ovens and pressure-resistant container inserts to use the serve to receive the samples and individually or in groups in the defined by the housing of the respective microwave oven th boiler room. The in operation from Microwave generator of the microwave oven in its Microwaves emitted in the boiler room penetrate the microwave permeable, plastic container wall and heat the in Sample inside the container. Because the container inserts made of plastic, they can be non-destructive can only be used up to pressures of approximately 200 bar. However, higher pressures, for example for extractions, desirable to increase the boiling point of the solvent and in this way the extraction at accordingly higher temperature and accordingly faster, d. H. more economical to perform. Flameproof container inserts made of metallic material withstand higher Pressures, however, due to their nature, are microwaves reflecting len rays, not for use in Suitable for microwave ovens.

It is an object of the invention, a device of the beginning mentioned type so that reactions under higher printing conditions and overall more economical could be carried out.

This task is characterized by the characteristics  of claim 1 solved. In this way the Reaction pressure prevailing inside the container insert not, as before, from the container insert itself, but taken up by the pressure vessel. This is for microwaves len impermeable and can therefore, for example metallic material, which compared to that still required for the container inserts microwave permeable materials a significantly has higher strength. It can also be non-metallic high pressure resistant materials are used as long as they are microwave-proof, d. H. electric and / or are magnetically conductive. Microwave permeable Material is only for closing the coupling opening required, their comparatively small dimensions compensates for the lower strength of this material, so that pressure reactions with the device according to the invention in the range of 1000 bar and more can.

The container insert can be used as a closure microwave the coupling opening at least in its area permeable and high pressure-resistant receptacle trained det be. It is preferably in the form of a two-part receptacle container, which consists of a sample receiving microwave-permeable sample container and one of these receiving, to close the coupling opening microwave-permeable at least in their area and high pressure resistant closure element.

According to a further embodiment, the container insert as one to an inlet and an outlet connection of the Pressure vessel connectable flow reaction insert educated. This is expediently in two parts at least for the purpose of closing the coupling opening in their area microwave-permeable and high pressure  most closure element and an arranged therein, high pressure resistant core element with one with its two Connect the ends to the inlet or outlet connection External thread formed. The core element can be microwaves permeable and / or absorbent. In the latter Case the sample is passed both directly through that through the Closure element penetrating microwave radiation as well as indirectly from that absorbed by the radiation heated portion of the core element. To achieve the sample container can have the same effect a microwave absorbing material.

According to a development of the invention, the receptacles are container, the flow reaction insert and the closure element ment with play in the pressure vessel and the core element can be used with play in the closure element and under the influence of the reaction temperature up to the full plant to the inner surface of the pressure container or the closure element mentes heat expandable.

The sample container is also advantageous with play can be used in the closure element and under the influence the reaction pressure and / or the reaction temperature to full contact with the inner surface of the closure elements and, if it has a greater height dimension than this has to the inner surface of the pressure vessel deformable or heat expandable. It is expedient the sample container is elastically deformable, being made of may consist of a fluoropolymer or copolymer which is also microwave-permeable.

The pressure vessel is preferably of circular cylindrical shape Cross-section designed to be the highest in this way Resist pressure. For reactions where the  Samples placed in the lower part of the pressure vessel the coupling opening in the cylinder wall training near the bottom wall of the pressure vessel. It is to achieve the highest possible temperatures the sample is expedient to design the sample container in such a way that he in the coupling opening or the closure element assigned wall area has its greatest wall thickness. In the area above the coupling opening, in which the Sample container a smaller, preferably its smallest Has wall thickness, a cooling arrangement on the pressure vessel ter be provided, for example when extracting of samples using a container insert in the form of a Soxhlet arrangement the most effective cooling possible of the evaporated solvent in the upper part of the Achieve pressure vessel.

The closure element is preferably made of plastic or ceramic material its shape is convenient that of a piece of pipe.

According to a development of the invention, the pressure vessel ter designed as a resonator to a high microwave density te and intensity inside the pressure vessel and to achieve a high degree of efficiency.

The dimensions of the pressure vessel are preferred changeable. This allows the microwave density and / or the microwave frequency, the field strengths and the field and / or amplitude distributions (H and E waves) the respective reaction to be carried out can be coordinated.

It is expedient to releasably on the pressure vessel Microwave generator or one leading to it To connect the conductor. The is also expedient Detachable connection of the conductor to the microwave generator.  

It is advantageous to change the pressure vessel its dimensions each one of several inserts different dimensions arranged interchangeably. These inserts can be of different pipe sections Wall thicknesses should be formed. Conveniently, can as an insert the appropriately trained closure element be used, in this case only in the area the coupling opening is microwave-permeable and otherwise is impermeable to microwaves.

The inserts can also be used as base plates at least different thickness dimensions. It is also possible to use a lifting device Height-adjustable base plate arranged in the pressure vessel to provide.

The invention is more preferred below based on some Exemplary embodiments and refinements with reference described in more detail on the drawing. Show it:

Fig. 1 shows a first embodiment of the device according to the invention in a schematic perspective representation,

Fig. 2 shows a second embodiment of the device according to the invention in a schematic perspective representation,

Fig. 3 is a sectional view of a pressure vessel according to Fig. 1 according to a first embodiment

Fig. 4 is a sectional view of a pressure vessel of FIG. 1 according to a second embodiment,

Fig. 5 is a simplified sectional view of a Druckbe container according to FIG. 1 according to a third embodiment, and

Fig. 6 is a sectional view of the device of FIG. 2 with a modified closure arrangement and pressure containers according to a fourth embodiment, for example.

The device according to the invention comprises for all embodiments a microwave generator in the form of a magnetron 1 in a conventional design with a decoupling device 2 , which has a flat circular cylindrical shape and several radially extending waveguides 3 , and a number of pressure vessels 4 , which are detachably connected to the waveguides 3 are. The decoupling device 2 also serves as a central mounting element for the magnetron 1 fastened to its underside and the pressure vessels 4 . Instead of the waveguide 3 , coaxial cables, not shown, can be used; in this case, the pressure vessels 4 are fastened directly to the decoupling device 2 , as shown in FIG. 2, but for a direct connection, shown in section in FIG. 6, without a conductor on the magnetron 1 .

The pressure vessel shown in FIG. 3, designated by the reference numeral 4.1 , has a circular cylindrical cross section, consists of a high-pressure-resistant metallic material, such as stainless steel or aluminum, and comprises a cylinder wall 5 , which is closed at its lower end by a bottom wall 6 and on has at its upper end a loading opening which can be closed in a pressure-tight manner by a closure arrangement 7 . The closure arrangement 7 comprises a bayonet closure outer cover 8 with a vent hole 9 and an inner cover 10 , which is pressed when the outer cover 8 is closed by a tensioning spring arrangement 11 supported on it against the upper free edge of the cylinder wall 5 . In the lower region adjacent to the bottom wall 6, a coupling opening 12 is formed in the cylinder wall 5 , to which the waveguide 3 is connected. Above the coupling opening 12 there is a cooling arrangement 13 on the pressure vessel 4.1 with a bush 14 which has a larger diameter than the cylinder wall 5 and is fastened to an upper and a lower flange projection 15 or 16 of the cylinder wall 5, for example by welding. The space 17 defined by these flange projections 15 , 16 and the socket 14 is connected in a manner not shown, for example by means of a quick coupling, to a likewise not shown, to a coolant supply (water) and a cooling device, for example a ball cooler construction leading line. At the upper free end of a central opening in the bottom wall 6 enforcing piston rod 18 of a lifting device, not shown, such as a pneumatic cylinder, a base plate 19 is fastened, which can be displaced when the lifting device is actuated in the pressure vessel 4.1 and can be locked at any height. The socket 14 extends from the lower flange projection 16 down over the bottom wall 6 , thereby forming a type of housing in which the lifting device is included.

The pressure vessel 4.1 is designed as a resonator, that is to say its cavity diameter and its cavity height are selected and so matched to the waveguide dimensions and the frequency range of the microwaves generated by the magnetron 1 that the field strengths desired for the reaction to be carried out and the desired field and / or Amplitude distributions (H and E waves) can be achieved. By determining the piston rod ge 18 and thus the base plate 19 at a corresponding lifting height within the pressure container 4.1 , the cavity height can be changed and the resonator can thus be adjusted; if necessary, the waveguide 3 is to be exchanged for a waveguide of different dimensions and / or to couple in a microwave radiation of a different frequency. If there is no lifting device, instead of the base plate 19, one of several base plates of different thicknesses can be interchangeably arranged in the pressure vessel 4.1 .

A container insert in the form of a two-part receptacle consisting of a closure element 20 and a sample container 21 removably arranged therein for receiving a sample 22 is removably arranged in the pressure container 4.1 . The closure element 20 in the form of a tube piece consists of microwave-permeable and high pressure-resistant material, such as. B. a corresponding plastic or ceramic material and is used for the pressure-tight closing of the coupling opening 12 ; accordingly, it extends with the required projection only in the area of this coupling opening 12 .

The sample container 21 consists of an elastically deformable, microwave-permeable plastic material, preferably PTFE, and has its greatest wall thickness in the area of the closure element 20 and its smallest wall thickness in the area of the cooling arrangement 13 . The height dimension of the sample container is slightly larger than that of the cylinder wall 5 of the pressure container 4.1 .

The sample container 21 can be inserted with play into the closure element 20 and together with it through the loading opening into the pressure container 4.1 . The dimensions and the materials used for the receptacle are chosen so that the closure element 20 is heat-expandable under the influence of the reaction temperature up to full contact with the inner surface of the cylinder wall 5 of the pressure container 4.1 and the sample container 21 under the influence of the reaction pressure and the reaction temperature is elastically deformable and heat-expandable until it abuts the inner surface of the cylinder wall 5 or the closure element 20 .

When using several closure elements that are microwave-permeable only in the area of the coupling opening and otherwise by z. B. a metallic coating are mikrowellenundurchlässig on its inner surface and having different wall thicknesses and, optionally, different benefit amount dimensions, always the one shutter member can be inserted into the pressure vessel 4.1 20 which tunes the cavity diameter, and thus the resonator properties on the respective durchzufüh Rende reaction.

The pressure vessel 4.1 described above is vorgese hen to carry out, for example, pressure digestion. For this purpose, by moving the bottom plate 19 by means of the lifting device into a raised loading position, the closure element 20 , possibly with the necessary wall thickness for the tuning of the resonator properties of the pressure vessel 4.1 to be carried out in the pressure vessel 4.1, and then the one with the Sample 22 loaded sample container 21 is inserted into the closure element 20 or the pressure container 4.1 . Subsequently, the lowering of the Bodenplat te 19 and thus the receptacle 20 , 21 to that working position, in the present exemplary embodiment game shown in Fig. 3, which corresponds to the adjustment of the resonator properties of the pressure vessel 4.1 to the pressure digestion to be carried out required. Finally, the pressure vessel 4.1 is closed in a known manner by means of the closure arrangement 7 . In this case, the part of the sample container 21 which projects beyond the cylinder wall 5 and is turned over to the outside via its free edge serves as a seal.

After switching on the magnetron, the microwaves 23 generated by the same are coupled through the waveguide 3 and the coupling opening 12 into the pressure vessel 4.1 in order to pass the sample 22 and the air inside the pressure vessel 4.1 with the air after passing through the closure element 20 and the sample vessel 21 to heat the oxygen required for the digestion under pressure increase. The high microwave density inside the pressure vessel 4.1 ensures a rapid temperature and pressure rise to the highest values. The former is responsible for the fact that the closure element 20 expands and thereby fits snugly and thus pressure-sealingly against the inner surface of the cylinder wall 5 of the pressure vessel 4.1 . The same applies to the sample container 21 , which, however, is deformed elastically primarily by the pressure rise and thus is full on the inner surface of the cylinder wall 5 ; in this way, the pressure inside the sample container 21 is absorbed by the pressure container 4.1 . Under the above-described reaction conditions, the atmospheric oxygen reacts by breaking the bond and forming new bonds, free radicals being formed which bind to the sample, so that the sample is oxidized, ie, broken down. The resulting gaseous products condense on the inner surface of the cylinder wall 5 assigned to the cooling arrangement 13 and are fed to the reaction again. After the digestion has ended and cooling has taken place, the pressure container 4.1 is opened by removing the closure arrangement 7 and the receiving container 20 , 21 is moved into the loading position by lifting the base plate 19 in order to then be removed. The reaction products of the digestion can then be separated from one another in a subsequent physical separation process.

The pressure vessel shown in FIG. 4, designated by the reference numeral 4.2 , corresponds fundamentally to that of FIG. 3 and differs from it only in that it has a connection 25 for a temperature sensor, not shown, and a connection 26 for a pressure sensor, also not shown , and that the bayonet closure outer cover 8 can also be fastened to the cylinder wall 5 by means of screws 27 . The connection 25 for the temperature sensor opens into the pressure vessel 4.2 via an opening 28 of the cylinder wall 5 which is opposite the coupling opening 12 and is sealed by the closure element 20 . The connection 26 for the pressure sensor is formed in the 7 Ordinance.

The pressure vessel 24 is provided for performing extractions using a Soxhlet arrangement.

This comprises the cooling arrangement 13 and an extractor, which consists of a cylindrical glass insert 29 for receiving a sample 30 to be extracted and the lower part of the sample container 20 for receiving a solvent 31 . The glass insert 29 is provided at about half the height with an annular flange 32 , which has through holes, not shown, and is supported on the circumferential step 33 formed by the free upper edge of the closure element 20 . At the upper free edge of the Glaseinsat zes 29 is followed by an upwardly diverging funnel 34 , which also has through holes, not shown, and extends to full contact with the sample container ter 21 . An overflow pipe 35 connected to the glass insert 29 in its upper region extends through the ring flange 32 into the upper region of the lower part of the sample container 21 which receives the solvent 31 . A so-called frit 36 made of PTFE is removably arranged in the glass insert 29 in a known manner.

After introducing the receptacle 20 , 21 containing the solvent 31 in the manner described above into the pressure vessel 4.2 , the frit 36 containing the sample 30 to be extracted is inserted into the glass insert 29 and this is then inserted into the receptacle 20 , 21 so that its ring flange 32 is supported on the stage 33 and the funnel 34 abuts the sample container ter 21 . Then the pressure vessel 4.2 is closed by means of the closure arrangement 7 in the manner also described above and the connection 26 for the pressure sensor is connected to a line, not shown, which leads to a control device of the magnetron 1 , not shown. The connection 25 for the temperature sensor is also connected to this control device in a manner not shown.

After the magnetron 1 has been switched on , the microwaves 23 emitted by it reach the solvent 31 in the manner already described in order to heat it. If the solvent is a non-polar solvent, the sample container 21 can consist of a microwave absorbing material which gives off the heat generated in it by the absorbed microwaves 23 to the solvent, which begins to boil under pressure increase.

The developing solvent vapor rises and passes through the through holes in the ring flange 32 and in the funnel 34 , condenses on the inner surface of the sample container 21 cooled by the cooling arrangement 13 above the funnel 34 and drips over this into the glass insert 29 . There it releases the substance to be extracted from the sample 30 and, when the overflow pipe level is exceeded, automatically runs back over the overflow pipe 35 into the lower part of the sample container 21 in order to evaporate again there. Since this cycle automatically runs again and again and only pure solvent evaporates, there is a continuous accumulation of the dissolved substance in the lower part of the sample container 21 . With the help of the pressure sensor, not shown, and the temperature sensor, also not shown, the pressure and temperature in the pressure vessel 4.2 are continuously monitored and the power of the magnetron l is correspondingly reduced when a maximum permissible value is exceeded. After the extraction has ended, the mixture can be concentrated in vacuo.

The pressure vessel shown in simplified form in FIG. 5, designated with the reference character 4.3 , is of the same shape and of the same material as the pressure vessel according to FIGS. 3 and 4 and is also designed as a resonator. It also includes the cylinder wall 5 , the bottom wall 6 , the bottom plate 19 with the piston rod GE 18 of the lifting device, not shown, the coupling opening 12 connected to the waveguide 3 and a cover 37 , which in operation by a clamping device shown in FIG free upper edge of the container insert designed as a flow reaction insert is pressed. In the lower region of the cylinder wall 5 near the bottom wall 6 , an inlet connection 38 opposite the coupling opening 12 is formed for the sample to be subjected to the flow reaction. The corre sponding drain connection 39 is located in the cover 37 .

The flow-through reaction insert comprises a closure element 40 in the form of a tube piece and a core element 41 arranged in this, both of which consist of microwave-permeable, high-pressure-resistant plastic or ceramic material and extend over the entire height of the pressure vessel interior. The core member 41 is provided with an external thread 42 which ends at both ends of the inlet and outlet 38 , 39 when the flow reaction insert 40 , 41 is inserted into the pressure vessel 4.3 (see FIG. 5). The closure element 40 thus serves not only for the pressure-tight closure of the coupling opening 12 , but also to define a flow channel in cooperation with the thread 42 of the core element 41 .

The flow-through reaction insert can be used with play in the same way as the receptacle according to FIGS. 3 and 4 in the pressure vessel 4.3 and, under the influence of the reaction temperature, lies well against the inner surface of the cylinder wall 5 ; by the same effect, the core element 41 is kept during the reaction in full contact on the inner surface of the closure element 40 . The pressure which occurs during a flow reaction, ie when the liquid sample flows through the flow channel formed by the thread 42 , is not taken up by the flow reaction insert but by the pressure vessel 4.3 .

1, the inventive apparatus of Fig. 6 differs from that of FIG. Characterized in that it has no waveguide and is provided for receiving pressurized containers 4.4, which are substantially identical to the pressure vessel of FIG. 5, however, no movable floor panel and thus have no lifting device. The pressure vessels 4.4 are connected directly to the magnetron 1 . The clamping device already mentioned in the description of FIG. 5 comprises a clamping cover 43 , which can be pressed against all covers 37 by screwing a nut 44 onto a centrally arranged cap screw 45 anchored on the decoupling device 2 .

Claims (28)

1. Device for triggering and / or conveying chemical and / or physical pressure reactions on samples by the action of microwaves, with the sample-receiving, at least partially mikrowelleable permeable container inserts which are arranged in a microwave-impermeable housing arrangement connected via at least one coupling opening to a microwave generator , characterized in that the housing arrangement comprises one or more pressure vessels ( 4 ) made of high-pressure-resistant material, the coupling openings ( 12 ) of which are microwave-permeable and high-pressure-resistant, and that in each pressure vessel ( 4 ), with its inner surface snugly fitting, a single container insert ( 4 ) is arranged. 2. Device according to claim 1, characterized in that the container insert is designed as a for the purpose of closing the coupling opening ( 12 ) at least in the area of microwave-permeable and high-pressure-resistant receptacle ( 4.1 , 4.2 ). 3. Apparatus according to claim 1 or 2, characterized in that the container insert as a two-part receptacle consisting of a sample ( 22 , 30 , 31 ) receiving, at least partially microwave-permeable sample container ter ( 21 ) and one receiving this, for the purpose of closing the coupling opening Ver ( 12 ) at least in the area of which microwave-permeable and high-pressure-resistant closure element ( 20 ) is formed. 4. The device according to claim 1, characterized in that the container insert as a to an inlet and an outlet connection ( 38 , 39 ) of the Druckbehäl age ( 4.3 ) connectable Durchflußreaktionsein set ( 40 , 41 ) is formed. 5. The device according to claim 4, characterized in that the flow reaction insert in two parts with a purpose to close the coupling opening ( 12 ) at least in its area microwave-permeable and high-pressure-resistant closure element ( 40 ) and a high-pressure-resistant core element ( 41 ) arranged in this with one with its two Ends at the inlet or outlet connection ( 38 , 39 ) connectable external thread de ( 42 ) is formed. 6. The device according to claim 5, characterized in that the core element ( 41 ) is microwave permeable and / or microwave absorbing. 7. The device according to at least one of the preceding claims, characterized in that the receiving container ( 20 , 21 ), the Durchflußreakti oninsatz ( 40 , 41 ) and the closure element ( 21 ; 40 ) with play in the pressure vessel ( 4. 1 , 4.2 ; 4.3 , 4.4 ) and the core element ( 41 ) with play in the closure element ( 40 ) can be used and heat-expandable under the influence of the reaction temperature up to the full contact with the inner surface of the pressure container ( 4 ) or the closure element ( 21 ; 40 ) are. 8. The device according to at least one of the preceding claims, characterized in that the sample container ( 21 ) has a greater height dimension than the closure element ( 20 ). 9. The device according to claim 3 or 8, characterized in that the sample container ( 21 ) with play in the closure element ( 20 ) can be used and under the influence of the reaction pressure and / or the reaction temperature to full contact with the inner surface of the closure element ( 20 ) or the pressure vessel ( 4.1 , 4.2 ) is deformable or heat expandable. 10. The device according to at least one of claims 3, 8 and 9, characterized in that the sample container ( 21 ) is elastically deformable. 11. The device according to at least one of claims 3 and 8 to 10, characterized in that the sample container ( 21 ) consists of a fluoropolymer or copolymer. 12. The device according to at least one of claims 3 and 8 to 11, characterized in that the sample container ( 21 ) in its the Koppelöff opening ( 12 ) or the closure element ( 20 ) associated wall area has its greatest wall thickness. 13. The device according to at least one of claims 3 to 12, characterized in that the closure element ( 20 , 40 ) is designed as a piece of pipe. 14. The device according to at least one of claims 3 to 13, characterized in that the closure element ( 20 , 40 ) consists of plastic, ceramic or the like. 15. The device according to at least one of the preceding claims, characterized in that the pressure vessel ( 4 ) consists of metallic material. 16. The device according to at least one of the preceding claims, characterized in that the pressure vessel ( 4 ) has a circular cylindrical cross section. 17. The apparatus according to claim 16, characterized in that the coupling opening ( 12 ) in the cylinder wall ( 5 ) of the pressure vessel ( 4 ) is formed. 18. The device according to at least one preceding claim, characterized in that the coupling opening ( 12 ) in the area of Bodenwan extension ( 6 ) of the pressure vessel ( 4 ) is formed. 19. The device according to at least one of the preceding claims, characterized in that the pressure vessel ( 4.1 , 4.2 ) in the region above the coupling opening ( 12 ) has a cooling arrangement ( 13 ). 20. The device according to at least one of the preceding claims, characterized in that the pressure vessel ( 4 ) is designed as a resonator. 21. The device according to at least one of the preceding claims, characterized in that the dimensions of the pressure vessel ( 4 ) are variable. 22. The device according to at least one of the preceding claims, characterized in that the pressure vessel ( 4 ) is detachably connected to the microwave generator gate ( 1 ) or a conductor ( 3 ) leading to it. 23. The device according to claim 22, characterized in that the conductor ( 3 ) is detachably connected to the microwave generator ( 1 ). 24. The device according to at least one of the preceding claims, characterized in that one of several inserts of different dimensions is arranged interchangeably in the pressure vessel ( 4 ). 25. The device according to claim 24, characterized, that the inserts as pipe pieces are different Wall thicknesses are formed. 26. The apparatus according to claim 25, characterized in that the closure element ( 20 , 40 ) is also designed as an insert. 27. The device according to at least one of the claims 24 to 26, characterized, that the inserts as base plates with at least different thickness dimensions are. 28. The device according to at least one of claims 21 to 26, characterized by a by means of a lifting device ( 18 ) in the pressure vessel ( 4.1 , 4.2 , 4.3 ) arranged vertically movable base plate ( 19 ).