DE858260C - Process for improving and applying the vortex tube effect - Google Patents

Description

Process for improving and applying the vortex tube effect The vortex ripening effect was designed by Georges R anque (Journal de 1'hysiclue [7] 112 [1933]) found. the The device used for this is shown in Figs. i and 2 shown. \ laii lets t in a cylindrical tube Air of several atmospheres pressure through the Flow in nozzle 2. The air partially relaxes wise in the nozzle and sometimes during the rotating generating flow in the direction of the pipe axis. As a result of energy exchange in the centrifugal field the kinetic energy flowing towards the center mending air partly to the outer layers transports and occurs there as heat. The in low energy located near the pipe axis Air fraction flows through one in the immediate vicinity the Diisü located aperture 3 as cold air. In the 1Landscliichteii, the air flows after the opposite pipe end and escapes there by a \ -entil4 as warm air. Later, R. H i 1 sch (Zeitschrift für Naturforschung6i [1946]), by searching for optimal dimensions using the test arrangement described above, achieved, for example, that at a pressure of 6 atii and a proportion of cold air of about a third of the air rivets flowing in through the nozzle 2, the cold air temperature was 45 ° lower was than the temperature of the incoming air. G. Burkhardt (Zeitschrift für Naturforschung 3 a,, 46 to 5i [1948]) tries to determine optimal dimensional relationships mathematically.

In any case, the processes always proceed in such a way that the amount of cold, on the one hand, corresponds to the amount of heat, on the other hand.

A substantial improvement in the vortex tube effect is made according to the invention achieved by the method described in the following deu, its method of operation on hand the schematic figures 3 to 9 is explained. This procedure identifies by placing the warm at the land zone in a vortex tube Gas inevitably separates and / or from the cold gas located in the vicinity of the pipe axis the cold gas located in the vicinity of the pipe axis by means of a correspondingly small sized gas jet promotes through a diaphragm and / or sucks from there, while the hot gas portion is cooled as soon as it contributes to the increase in the cold gas portion target.

When working according to Fig. 3 and 4, the flowing in through the nozzle 2 is Compressed gas is partially relaxed in it and gradually merging into the pipe bend Channel 5 set in rotating motion, as shown by the arrows in Fig. 4. Through a Cone 6 becomes. the gas located in the edge zone is prevented from entering the area of the cold gas penetrate in the middle of the pipe, like the flow path indicated by arrows in Fig.3 indicates that <let <read cold gas with a lower temperature than <lern hitherto known vortex tube flows off through the diaphragm 3. Through this way of working at the same time the length of the vortex tube that was previously necessary is shortened considerably.

h: a further substantial improvement of the vortex tube effect achieved in a modified mode of operation according to Fig. 5 and 6. That through the nozzle 2 pressurized gas flowing in, which is partially relaxed in it, flows into the pipe bend in one gradually passing channel 5 set in rotating motion. Through one to the pipe i concentrically arranged hollow core 7 is the gas located in the edge zone, on which the centrifugal force acts, causes the pressure drop from the annulus 8, between tube i and core 7, to follow the interior 9 of the core 7 through opening r i to enter the zone of the cold gas expanded to low pressure and to flow away together with this through the diaphragm 3. The necessary cooling of the hot gas portion entering the annular space 8 is attached to the pipe i Causes cooling surfaces ok. With this procedure it is now possible, with the appropriate Shaping and dimensioning of the annular space 8, the opening i i and the spacing, the latter from the diaphragm 3, only a small fraction of the amount of gas from the outermost edge zone dissipate, which then has a higher temperature according to the heat balance. Latter allows a large heat exchange with the coolant, so that by reunification of the two gas quantities a total cooling remains, that of the exchanged Corresponds to the amount of heat. This is the maximum achieved with the original vortex tube Temperature reduction significantly exceeded.

The method described above can be carried out in a number of ways expand and can according to the invention, for example, on the liquefaction of gases be expanded. The method of operation of the process is then shown schematically in Figure 7 shows as follows. The compressed gas supplied by a compressor, not shown enters a counterflow heat exchanger 13 at 12, in which it is pre-cooled. In the steady state, gas components that have already been liquefied here are replaced by a Valve 14 drained by operating a handwheel 15. The non-liquefied one Gas portion is expanded in a vortex tube 16. This vortex tube can be from the Design according to Fig.5 differ insofar as the cooling is omitted and you can get through the annular space 8 (Fig. 5 and '6) flowing small amount of hot gas through a valve 17 drains. The liquefied gas components collect in the container 18, and the not Liquefied and re-evaporated gas components flow through the countercurrent heat exchanger 13, cooling the pressure gas flowing in the opposite direction, and through a connection piece i9.

Furthermore, according to the invention, several vortex tubes can be used in the method can be connected in series in pressure stages, as shown in Figure 8, for example, in that the outflowing cold gas enters the nozzle of the next vortex tube and so gradually relaxes, resulting in a correspondingly greater temperature decrease results.

A modified mode of operation of the method results according to the invention through the switching of several vortex tubes as shown in Figure 9. This is a vortex tube 20 removed a larger proportion of hot gas, cooled in a cooler 2i and a further vortex tube 22 is supplied. The amount of cold gas flowing from both vortex tubes can be combined or the cold gas flowing off from the vortex tube 22 can, as shown in dotted lines shown, used to pre-cool the pressurized gas flowing into the vortex tube 20 will.

The application of the vortex tube effect and its possible combinations are not limited according to the invention to the examples in Figs. 7 to 9, but you can vortex tubes z. B. also for air conditioning or with the easy control option the proportion of cold and warm air for controlling the temperature of air conditioning systems, even at low levels Print and, if necessary, then in its form that has not yet been improved, use.

Claims (7)

PATENT CLAIMS: i. A method for improving and applying the vortex tube effect, characterized in that the hot gas located at the edge zone of a vortex tube is inevitably separated from the cold gas located in the vicinity of the tube axis and the latter is conveyed through a diaphragm and sucked off from there by means of a correspondingly small gas jet, while the hot gas portion is cooled before it contributes to the increase of the cold gas portion (Fig. 5 and '6). 2. A method for applying the vortex tube effect according to claim i, characterized in that that for the purpose of gas liquefaction, the compressed gas before entering a vortex tube (16, Fig. 7) through a countercurrent heat exchanger (13, Fig. 7), in which it is by means of of the cold gas proportion, which is relaxed in the vortex tube, and is kept as large as possible in countercurrent pre-cooled is, while one is kept as small as possible or equal to zero Hot gas is discharged through a controllable valve (i7, Fig.7). 3. Procedure for the application of the vortex tube effect according to claims i and z, characterized in that that two or more vortex tubes are connected in series (Fig.8) in such a way that that the cold gas portion of a compressed gas partially expanded in a vortex tube is further relaxed in a subsequent vortex tube. 4 .. Procedure for Application of the vortex tube effect according to claims 1 to 3, characterized in that that when a larger proportion of the hot gas is still under pressure, the from a vortex tube (2o, Fig. 9) via a cooler (2 i, Fig. 9) to another Vortex tube (22, Fig.9) is fed, after which either of the two vortex tubes outflowing cold gas quantities are combined or that from the second vortex tube (22, 9) outflowing cold gas for pre-cooling the in the first vortex tube (20, Fig. 9) incoming pressurized gas is used. 5. Method of using the vortex tube effect according to claims i to 4, characterized in that by means of the method in cooperation the air temperature and humidity is controlled with an air conditioning system. 6th Vortex tube for carrying out the method according to Claims 1 to 5, characterized in that that on the hot gas side of a vortex tube a cone (6, Fig. 3) in the axial direction is arranged, which inevitably separates the layers of the hot gas from those of the cold gas separates. 7. vortex tube for carrying out the method according to claim i, characterized in that a hollow core (7, Fig. 5) concentric on the hot gas side of a vortex tube is arranged, which inevitably separates the layers of the hot gas from those of the cold gas separates and the hot gas on the pipe wall equipped with cooling elements (io, Fig. 5) (i, Fig. 5) leads along, in such a way that the gas is cooled with falling pressure after the cavity (9, Fig. 5) of the core (7, Fig. 5) and through an opening (i i, Fig. 5) flows together with the cold gas through an orifice (3, Fig. 5).