DE1557033A1 - Method and device for mixing gases - Google Patents

Description

Method and apparatus for mixing gases The present invention deals with a mixing process through which different gases flow in the same way Ratios are to be mixed, as well as devices for performing this Procedure.

According to the invention, a gas which is referred to below as propellant gas is used is passed through the nozzle of an ejector, with the pressure and temperature upstream of this nozzle are kept constant. This is how you create a negative pressure in the ejector. This negative pressure is used to generate a second gas suction, -at which the pressure and the temperature in the vicinity of the suction point are constant, the suction taking place through a Venturi nozzle, which is the suctioned Current at this temperature and pressure in places the speed of sound; gives. In this way, a mixture with a constant quantitative ratio is obtained Gases without the need for apparatus with moving organs.

With regard to the invention, it should be remembered that it is possible to use venturi nozzles to train the sense proportionately slow flow the narrowest point of the nozzle reaches the speed of sound and in the divergent part again falls below the speed of sound and that there is such a flow To obtain, it is sufficient to feed such a nozzle with a pressure of about 5 to i5 is above the absolute pressure that prevails in the vicinity of the outlet.

In this way, the method according to the invention allows it to be kept constant the calorific value of an increase from gas streams or keeping the humidity constant a mixture of gas streams or steam flow.

The following non-limiting explanatory purposes Description of exemplary embodiments of the invention with reference to the accompanying drawing it is easy to understand the different characteristics and the way make how the invention can be implemented. The one from the drawing and the Description resulting special features are part of the invention. In the drawing Fig. 1 shows a longitudinal section through a gas mixing device according to the invention, FIG. 2 shows a section along line II-II in FIG. 1 showing a valve, FIG. 3 shows a Section through a second embodiment of a mixing device on which a first Device for regulating the flow rates of the gases to be mixed is provided, Fig. 4 shows a section through a variant of the previous embodiment in which an automatic device for regulating the flow rates is provided, Fig. 5 shows a section along line V-V in FIG. 4 through the device with automatic Regulation of gas flows, Pig. 6 shows a section along line VI-VI in Pig. 7 through a Another embodiment of a mixing device with a third device for Regulation of the flow rates, FIG. 7 shows a section along line VII-VII in FIG. 6 and Fig. a section through a variant of the in Figs.

3 and 4 shown execution standards.

The gas mixing device shown in Fig. 1 has a nozzle 1, the upstream part of which is shaped convergently and which has a cylindrical Piece 2 merges into a diffuser 3, a nozzle 4 forming the propulsion jet, whose Thread 5 also has a Tflit thread, but is not shown can accommodate. The nozzle 4 screwed to the support 1 has a bottleneck 6, its Dimensions are chosen so that the propellant gas at the speed of sound during normal operation accepts.

The sucked in gas penetrates through a VenturidWse 7 into the nozzle 1 a. The nozzle is designed so that the sucked gas flow on At the cost of a small loss in throughput, the speed of sound is reached. at In this embodiment, the nozzle 7 is open to the ambient air and opens into the annular space 8 surrounding the nozzle 4; but the nozzle could also be attached to a closed space or connected to a line.

A valve 9 (Fig. 2) lies within a cylindrical cavity 10, which is provided between the divergent part 11 of the venturi 7 and the space # is. The valve 9 is formed by a circular disc 12, which has flexible Arms 13 is connected to a ring 14 between the nozzle 1 and the nozzle 7 is inserted. The valve 9 can also be another check valve of known type be.

The method according to the invention is carried out in the following manner : The nozzle 4 is rushed under an absolute pressure 2 a temperature T which is im are essentially constant, fed with a propellant gas, the flow of which in the bottleneck 6 speed of sound reached. The flow rate Q of this gas is proportional to print P.

The gas jet that is formed by the propellant gas at the outlet of the nozzle 4 is sucked in through the nozzle 7 through a second gas upstream of the Nozzle 7 is kept at bucket temperature T2 and at an absolute pressure P2, the essentially are constant, this second gas being the ambient air can be.

The flow of this gas reaches the speed of sound in the bottleneck 15 of the nozzle 7 and its flow rate Q2 is substantially proportional to the pressure P2. The sucked in Current is deformed when the valve 9 is in the normal position and mixes with it Propellant gas in the cylindrical part 2 according to the constant flow rates Q1 and Q2.

The valve 9 can with a certain displaced amount between two Open or close the limits of a dynamic pressure. So if the back pressure is a limit reached, dle is above the limit at which the speed of sound im Bottleneck 15 stops, one that cannot be operated manually or automatically does not prevent The device shown dAe further feeding the propulsion jet nozzle 4. Then arises In the Stut3en 1 a Staudruti and the valve 9 lies at the valve seat 16 and prevents so the escape of the gas mixture into the space that contains the sucked gas.

Fig. 3 shows a gas mixing device that enables the flow rate of the propellant gas and the sucked gas to vary, but with the quantity variance tnis is essentially maintained.

The method according to the present invention then works on the same Way operated as in the device shown in Fig. 1, however, is through the possibility of regulating the amount of fluid is perfected.

The propellant gas penetrates through a channel 17 via a first passage 19 into the channel 1ba, while a second passage 20 has a flat and through the Disk 21 limited diffuser forms. An annular seat 22 enables the closure of the passage 20. A channel 1bb connects to the channel 18a and leads to the nozzle 4 leads.

The sucked in gas flows through the opening 23, thereafter through the passage 24, which in turn forms an annular diffuser, and through the disc 25 is limited, and then through the channel 26 to into the To penetrate nozzle 1. An annular seat 22a allows the passage to be closed 24.

The discs 21 and 25 are firmly connected to a rod 2, the at 28 screwed into the outer wall of the channel 18a and in one with a Seal 30 equipped bore 29 is axially guided. The Stane 27 can with a Handwheel 91 be provided.

The arrangement just described is provided with two flat diffusers the regulation of the amount of fluid by changing the flow cross-sections 20 and 24. For the purpose of regulation the handwheel in the appropriate Direction of rotation rotated, with an axial displacement thanks to the thread 28 the rod 27 and thus also the disks 21 and 25 receives. You create one like that Change of the passage cross-sections 20 and 24 with a constant ratio of the cross-sections.

When in the Pig. 4 and 5 device shown is the control the passage cross-sections 20 and 24 by automatically operating means as a function made by the flow rate of the gas mixture consumed by the consumer. In this case, neither a handwheel nor a thread is provided on the rod 27; the thread 28 of the outer wall of the channel 18a is replaced by a bore 32, which is equipped with a seal 33.

Those parts that are also addressed in the embodiments according to the Figures appear have the same reference numbers here.

The rod 27, on which two discs 21 and 25 are attached, dent Position by shoulders 94 and 35 and screws 36 and 37 opposite openings 19 and 23 are fixed, a flexible membrane d is firmly connected. This membrane separates two chambers 39 and 40 of a cavity 41 from each other, the chamber 40 over a power 43 with the cylindrical part 2 of the nozzle and the other chamber 39 is connected to the diffuser 3 via a line 42; lines 42 and 43 serve to supply the pressure prevailing at the taps to chambers 40 and 39.

The rod 27 penetrates the cavity 41 through a seal 46 provided bore 45 a.

To facilitate assembly, the opening 23 can be detachable Cover flange 47 be provided. The membrane 9 and the walls 4 and 49 of the cavity 41 are connected to one another at their periphery and between two rings 50 and 51 held together by rivets or bolts.

The entire control device is on the channel 26, for example by means of support rods 52 and 53 held.

This device enlarges the passages 20 and 24 of the propellant gas and the sucked in gas, the greater the static pressures in channel 44 and grow in the cylindrical part 2, that is, with an increase in the flow rate. The device allows the functions of the jet pipe to be adapted to requirements of the user without affecting the ratio of the flow rates of the mixed gases will be changed.

In the embodiments of the invention shown in FIGS. 6, 7 and 8 are shown, the control of the ratio of the flow rate to a made another type.

In the embodiment according to FIGS. 6 and 7, the is upstream lying part 54 of the connecting piece 1 through a flange 55 closed, which is welded, for example, to the supply channel 17 for the propellant gas The propellant gas nozzle 4 is between the upstream part 54 of the connecting piece 1 and the channel 17 mounted so as to be axially displaceable. Two annular seals 56a and 56b provide the seal between these two members and the propellant gas nozzle 4, which together with the nozzle 1 delimits an annular passage, the convergent-divergent runs and has a bottleneck 57. A core 58 that is upstream and downstream is pointed, is arranged in the divergent part of the propellant gas nozzle 4, together with the it delimits a second annular passage with a bottleneck 59. The pole 60 of this core 58 is screwed into a transverse arm 61; which in the channel 17 through Rivets 62 or is attached by welding.

The nozzle 4 can be fixed relative to the core 58 with the aid of a pin 63 be that slides in a cut-out 64 of the nozzle 1.

A screw 65 which is screwed into a threaded hole in the connecting piece 1 is, the nozzle 4 can hold in a selected position. Everyone position the Nozzle 4 corresponds to two particular values for the cross sections of the bottlenecks 59 and 57 and accordingly also certain values of the flow rates of the propellant gas and the sucked gas.

The method according to the invention is executed here in the same way, as in the arrangement shown in Fig. 1, but is due to the regulation of the flow rates perfected by means of the displacements of the nozzle 4.

One can see the shape and relative positions of the walls that the limit annular passages, in such a way that determine the ratio of the Flow rates for at least part of the path of the nozzle 4 remains constant. This can either be done by hand or by an automatic control device such as it is shown for example in Fig. 4, be shifted.

The variant according to FIG. »Allows the implementation of the invention Procedure in an analogous way.

In this pall the nozzle is fixed, while two fixed needles allow the regulation of the flow rates of the propellant gas and the sucked gas. The propellant gas is supplied to the nozzle 4 through lines 17, 18a and 1Bb. The sucked in Gas flows through openings 66 of housing 67 and channels 68a and 68b in FIG the nozzle 1.

The needles 69 and 70 are extended by rods 71 and 72.

A rod 73 is screwed into the base of the needle 69. The poles 71, 72 and 73 are guided in bores 74, 75 and 76, which bores with circular Seals 77, 78 and 79 are provided. The rod 71 is provided with a collar 80, on which a spring 81 accommodated in a cap 82 is supported. Against rotation the needle is secured by a pin 83 on the collar 30, which is in a slot of the Cap 82 slides.

The needles can be opened in this way by turning a screw 84, which is screwed onto the threaded end of the rod 71, axially displaced will. The relocation of Needles changes the passage cross-sections, at the bottlenecks 85 and 6 and consequently the flow rates of the propellant gas and of the sucked in gas. One can determine the shape of the needles so that the flow rates can be regulated at a constant ratio.

The invention is not limited to the described embodiments, but also covers those embodiments that are technically equivalent by applying Receives funds. In particular, you can have several propellant gases and several sucked gases mix with each other by using several propellant gas nozzles, preferably symmetrically Porm and several Venturi nozzles are arranged on the nozzle 3.

Claims (15)

Claims: 1. Method for mixing gases with exactly constant Quantities, characterized by the following process steps: generation at least one flow of propellant gas in a propellant gas nozzle, maintaining a constant pressure and a constant temperature of this propellant gas upstream the nozzle, supplying at least one second gas downstream of the nozzle by means of at least one further nozzle, generating a sound velocity flow of this second gas, suction of this second gas or these second gases through the negative pressure created by the suction of the propellant gas. 2. The method according to claim 1, characterized in that the The flow of the propellant gas is kept at the speed of sound in places. 3. The method according to one or both of the preceding claims, characterized in that the passage cross-sections in which the flows Reach the speed of sound, can be varied. 4. The method according to claim 3, characterized in that the cross-sections can be varied while maintaining their constant ratio. 5. Device for mixing streams of different gases, marked by an ejector with at least one nozzle (4) from which a propellant gas flows and that flows into a space that limited by the wall of the ejector is and at least one supply opening (7) for gas to be sucked in, which is a bottleneck (15), in which the speed of sound arises and which is also in the by the wall of the ejector opens into the limited space. 6. Apparatus according to claim 5, characterized in that upstream the outflow opening of the propellant gas nozzle (4) means for generating the speed of sound of the propellant gas are provided. 7. Device according to one or both of claims 5 and 6, characterized characterized in that the said passage valves for regulating the flow of the Has sucked gas. 8. Device according to one or more of claims 5 to 7, characterized by further means of varying the flow rate while maintaining a constant ratio between the flow rate of the propellant gas and the flow amount of gas sucked in. 9. The device according to claim 8, characterized in that said Means have two disks (21, 25) which are fixed to one another via a rod (27) are connected and the opposite of inlet openings (19, 23) for the propellant gas and the sucked gas are arranged (Fig. 3, 4). 10. The device according to claim 8, characterized in that the said means have needles (69, 70) which are fixed to one another by a rod (73) connected (Fig. 8). 11. Device according to claims 9 or 10, characterized characterized in that it has means for displacing the rod (27; 71, 73, 72) longitudinally has its axis. 12. The device according to claim 11, characterized in that the Means for displacing the rod are formed by a flexible membrane (38), which is subject to the pressure difference, the upstream and downstream of the divergent Part (3) of the ejector prevail (Fig. 4). 13. The device according to claim 8, characterized in that the Means for varying the flow rates through at least one propellant gas nozzle (4) are formed between the walls of the ejector (1) and a solid core (58) is axially movable (Fig. 6). 14. The device according to claim 13, characterized in that means (63) are provided for moving the nozzle (4). 15. Device according to one or both of claims 13 and 14, characterized characterized in that the core (58) is downstream. eu-pointed and in a divergent one Passage of the nozzle (4) is arranged (Fig. 6).