DE1054651B - Method and cell wheel pressure exchanger for compressing a gas - Google Patents

Description

Process and cell wheel pressure exchanger for. Compressing a gas The invention relates to a method for generating pressurized gas by means of a cellular wheel pressure exchanger and a pressure exchanger suitable for carrying out this process.

It has already been proposed to put gas, for example air, in the cell wheel a pressure exchanger to compress that high pressure gas into the low pressure air containing cells was introduced. During the pressure equalization in the cell The air is compressed by the direct action of the high pressure gas. The high pressure gas, which can be hot air, for example, is known in this case. Arrangement fed to the cells through a suitable pipeline while the compacted. Air is removed from the cells through another pipe. That to be condensed high pressure hot gas is supplied by a heating system that is external to the cells is arranged.

'\ #, on the other hand, it is known to have the entire in the inlet stage of a Air supplied to the pressure exchanger (with the exception of the air required for flushing purposes) to mix with fuel vapors and ignite the entire mixture, after which the combustion gases in their entirety through one and the same outlet duct be removed from the cellular wheel. In this arrangement, the fuel is with Air is mixed immediately in the cells so that none of the fuel gases are separated Gas compression takes place. With such an arrangement one would. second Introducing gas into the cells, then by design would be the known Arrangement dependent type of fuel supply a thorough mixing of the combustion gas unavoidable with the gas to be compressed. As a result, it could be with the known arrangement, neither clean gas could be supplied, nor could the combustion products be discharged separately from the clean gas.

In contrast to the arrangement already proposed and to the known one Arrangement, the present invention aims to solve the problem, in a pressure exchanger, at which in the individual. Cells undergo gas compression as a result of gas combustion takes place, nevertheless to obtain compressed gas as pure as possible. Which of course represents a significant technical advantage over the known arrangements.

According to the invention is a method for Verdrich.ten a gas in a Zel: lenrad pressure exchanger by means of combustion within the cells. des Druckaus.taus.chers, which -by the order below Measures is marked: a) Charging the cells: partly with a flammable gas mixture and partly with the gas to be compressed, b) igniting the combustible gas mixture of one end of the cell with the cell closed on both sides for the purpose of gas compression, c) opening the end of the cell opposite the ignition end and d) sharing the Combustion pressure of the burned partial load to push out the compressed Gas.

This ensures that the pressure exchanger is essentially pure compressed gas not contaminated by combustion products.

In the known arrangements results from the blowing process inevitably a substantial turbulence of the cell contents. In the same way With the known arrangements within the cells, there is a further turbulence in that fuel is at a higher pressure than the ambient pressure in the cells are injected. This turbulence necessarily causes a Mixing the fuel with the entire cell content.

In contrast, according to the method according to the invention, the gas, which flows into a smooth-walled channel, relatively little turbulence. As a result of that According to the invention, the fuel is injected into the gas flow and the Injection direction corresponds to the flow direction of the gas flow, the fuel cloud spatially limited. so that they do not cover the entire cross-section of the inlet duct can expand away. This results in a so-called stratified one Flow within the inlet duct, the one layer of pure air and the other layer consists of a fuel-air mixture. This explains that with a pressure exchanger according to the invention actually almost completely pure compressed gas is supplied, while on the other hand the products of combustion for can be withdrawn via a separate channel.

The invention also includes a pressure exchanger for implementation of the procedure. the invention. Such a Druckau.stauscher is characterized in that it has a channel for supplying the gas to be compressed, in the wall of which a fuel injection device is arranged, by means of which Fuel is injected into part of the supplied gas. The construction and operating data of such a pressure exchanger are according to a feature of FIG Invention chosen so that the part of the gas to be compressed after entering the cells have the tendency at the end facing the supply channel. of cells to stay. Furthermore, in such a pressure exchanger, they are spatially separated from one another separately arranged gas discharge and exhaust channels are provided, each connection have opposite ends of the cells with a miserable supply channel.

Two preferred embodiments of the invention are now set out below Described with reference to the schematic drawing.

Fig. 1 is a development of the cell wheel, a pressure exchanger, which revolves relative to fixed channels; Fig. 2 shows a modification of the Embodiment according to FIG. 1, in which a transfer channel is installed.

B-ei of the embodiment of the invention shown in Fig. 1 moves the cell wheel 1 shown in the development in the direction of arrow 2 between End plates 3 and 4. A single cell in position 5 will now be considered will. This is filled with fresh air, which will be described later Way is fed through the channel 6. Part of the flowing in through channel 6 Air receives fuel from a spray nozzle 7 which moves in the direction of the movement of the cellular wheel is arranged in the wall of the channel 6. The resulting fuel-air mixture enters cell 5 just before it passes through edge 8 of the duct wall 6 is completed. The fuel is in the flow direction in the channel 6 in this way injected that. it does not extend over the entire flow cross-section. w ° g spread can, but rather is forced to occupy only part of the flow cross-section. If necessary, the fuel can also spread out in the cross-section of the duct be prevented by a partition .in the channel 6. Cell 5 contains in the position now on the one hand fresh air and on the other hand a fuel-air mixture. The interface between fresh air and mixture is shown in the drawing by a broken line shown. The mixture will ignite when the cell turns on a glow plug 10, which is mounted in the end plate 4. While the pressure and volume of the filling increase during combustion. The fresh air becomes as a result compressed in the part of the cell located downstream and then through ejected the outlet passage 11. The cell terminates this channel itself timed, and the pressure in the duct is adjusted so that none Combustion gases can escape from the cell. These latter gases remain: in the cell until the same is in front of the exhaust duct 12, through which the gases expand, leaving behind a negative pressure in the cell, which the inflow of fresh air into the cell through the inlet channel 6 favors. The cycle for the cell in question then begins anew.

If two gases of different pressures suddenly become in one another Brought into contact, such as B. when a cell of a pressure exchanger before a Channel comes to lie, which carries gas under a pressure which is different from the pressure: of the gas in the cell, .then a wave or a pulse is generated, which or which travels through the cell at about the speed of sound. This can be both a compression and an expansion wave, depending on the situation whether the pressure in the cell is lower or higher than that in the duct. There are Known pressure exchangers in which the performance is achieved by utilizing these waves is increased. Improvements have also been made through the use of the known Overflow ducts. The efficiency of the method described above can be similar Way can be improved, and Fig. 2 shows how the simple apparatus of Fig. 1 can be modified to achieve such improvements.

In the example of Fig. 2, the construction and operation of the Cells and the channels related - in a manner already known - to the Gas flow, so that one of the compression and expansion waves in an efficient manner can be used to aid in the filling or emptying of cells. The ways of Compression wavefronts against the solid pipeline are in full lines pulled out, while the paths of the expansion wavefronts are shown in dashed lines are.

The emptying of a cell in the exhaust duct 12 is now supported by an expansion wave 13 traveling through the cell and am upstream located end of the cell creates a strong negative pressure. It then becomes the Inlet caution to the cell opened, which in the escape of the exhaust gases in the channel 12 is quickly filled with fresh air. The exhaust duct is then passed through another Movement of the cell is closed, and a compression wave is generated which migrates towards the open end of the cell and one in the fresh charge of the cell Pressure builds up. The cell is then closed off by the edge 8 of the inlet channel. Under the operating conditions envisaged by the design, a considerable amount can be achieved Degree of charging of the cell, and in this way a part of the in energy contained in the exhaust gases is recovered; so will the mass of the gas flowing through the machine is increased.

The compression of the cell contents before combustion is further increased by the return of previously compressed air via an overflow channel 14 known per se. This method is also improved by expansion s and compression waves 15 and 16, respectively. Each wave travels through the cells, sets the cell contents in motion and is reflected on the face plate 4. The reflected waves 17 and 18 migrate back to the open end of the cells and bring the cell contents to rest in the expanded or compressed state. A cell, the content of which has been pre-compressed in this way, then reaches the glow plug 10. The combustion of the fuel-air mixture generates a series of small compression waves, not shown here, which travel through the cell at a greater speed than the expanding gases and thereby the Compress air at the other end of the cell. The cell is then opened to the conveying channel 11, in which latter the pressure is slightly lower than that in the cell. The delivery of the compressed air is supported by the expansion wave generated as a result of this pressure difference. Some of the air remains in the cell in order to be put back into circulation via the channel 14 for the purpose of precompressing the contents of the other cells.

In these examples, the rotary valve can be used as in the earlier pressure exchangers from the outside .her are driven by a motor; but it can also be driven are suitably bent by the action of air or gas Parts of the cell wall. The arrangement of the channels can be around the perimeter of an individual. Cell wheel are repeated several times, so that each cell with one revolution of the Cell wheel goes through several cycles. Also the optional means of generation relative rotation between the cells and the channel part previously announced could be used in practicing the present: invention; d. H. in other words, the cells. could be arranged stationary during the Channel part rotates. Furthermore, the air could be compressed in several stages, by conveying it from one cellular wheel to the next, or by means of several Pressure transfer channels.

Should the compressed air be used to drive a turbine or for a Process or for nozzle propulsion purposes and it is included to heat, then this can be continuous or intermittent as required take place in a combustion chamber arranged outside. Optionally, you can go through it Achieve suitable supply of fuel and arrangement of the channels. That the Conveying channel 11 leaving air a significant proportion of hot combustion gases contains. With such an arrangement, there may be no need for a special exhaust duct.

Claims (5)

PATENT CLAIMS: 1. Method for compressing a gas in one Rotary wheel pressure exchanger by means of combustion within the cells of the pressure exchanger " marked by. the order of the following measures: a) charging the cells partly with a combustible gas mixture and partly with the gas to be compressed, b) Igniting the combustible. Gas mixture from one end of the cell closed on both sides: sener cell for the purpose of gas compression, c) opening the opposite of the ignition end End of the cell and d) shared use of the combustion pressure of the burned. Partial load to expel the compressed gas. 2. Pressure exchanger for carrying out the process according to claim 1, characterized by a. Channel (6) for feeding the material to be compressed Gas., In the wall of which a fuel injection device (7) is arranged, by means of which fuel is injected into part of the supplied gas. 3. Pressure exchanger according to claim 2, characterized in that its Konstruktio.ns- and operating data are selected so that the part of the gas to be compressed after Entrance .in .the cells (9) tends to be at the one facing the supply channel (6) End of the cells to stay, and further characterized in that the spatially separately arranged gas discharge (11) and exhaust ducts (12) each Have connection with the ends of the cells facing away from the feed channel. 4. Pressure exchanger according to claim 3, characterized in that the cells (9) on their way from the gas supply channel (6) to the gas discharge channel (11) with their respective facing the gas supply channel Run past the ends of an ignition device (10). 5. Pressure exchanger according to claim 4, characterized by a known overflow channel (14) with the the feed channel (6) facing away from the cell ends (9) can connect, wherein that branch: this overflow channel, through which the overflowing gas In the cells flows in between the gas supply channel (6) and the ignition device (10) is located, while the branch through which the overflowing gas comes from flows out of the cells, between the gas discharge duct (11) and: the exhaust duct (12) is arranged. Publications considered: German patent specification No. 512 289; German patent application H 14056 I a / 46f (published on February 17. 1955).