DE572395C - Method for obtaining a pressure medium for remote power transmission - Google Patents

Description

Method for obtaining a pressure medium for remote power transmission The present invention is based on the peculiar and novel knowledge that deflagration combustion turbines in contrast to reciprocating internal combustion engines and constant pressure internal combustion turbines one have particular suitability for the economical production of a pressure medium. These Particular suitability is that with detonation combustion turbines without difficulty the pressure under which the fire gases have to be conveyed for energy transfer, by setting the counterpressure of the exhaust gas turbine can be realized without the inevitable in piston internal combustion engines, damaging repercussions on the engine or the profitability of the Process-excluding lowering of the degree of efficiency in impulse turbines occurs. The invention consists in the fact that the pressure medium, which is in the manner of compressed air to serve for remote power transmission, inPerpuffungsbrennkraftturbinenanlagen in Form of tensioned fire gases is generated. By the fact that by become known and already proposed methods there is the possibility of the heat content of the fire gases to withdraw this fully or partially usable before forwarding can be done by The method according to the invention to be feared initially during the forwarding Heat losses can be reduced to any arbitrarily presettable amount. With that, however, the economic efficiency of the new process also occurs compared to the Generation of compressed air to days because pickling. Compressed air generation process the required Pressure height through mechanical reduction of air-filled rooms, d. H. under effort quite. Considerable mass and friction work must be created while this Pressure height in the process according to the invention with a decisive restriction the negative work mainly due to the incineration process, d. H. with the high efficiency of the same is available.

The fact that pneumatic power transmission means are also competitive with the generally used electric long-distance bike transmission is the case even when using expensive compressed air, compare, for example, the compressed air plant in the city of Paris, which is still in operation today. This fact lies in the special properties of electrical power transmission. The drive machines operated with electrical energy, in particular the supply lines, switching and safety devices belonging to them, are parts that have a high level of sensitivity, e.g. B. against moisture, mechanical and chemical influences. They are therefore not suitable for robber businesses, e.g. B. for forges, smelting works, rolling mills, mines, etc. Furthermore, electrical power transmission is associated with a certain degree of danger, since, in order to be economical, it has to work with high voltages at which sparks can be prevented with certainty only with great difficulty. Such sparks are particularly dangerous when it comes to companies in which ignitable mixtures occur, e.g. B. in mines and chemical plants. Finally, it is a particular disadvantage of electrical power transmission that the only possible drive machines are motors which have a relatively low adaptability to many requirements of the driven machines. Such engines can be run economically only iunlaufend, so that it is z. B. cumbersome gear is required if the revolving movement is to be converted into a reciprocating movement. So that the electric drive motor does not become too expensive, it must be designed at high speed, so that expensive and unreliable transmissions may be necessary as a result. Finally, speed control in electrical power transmission is a task which has to be carried out by relatively complex and expensive means. All of these devices for artificially adapting the electric drive motor to the conditions given by the work machine entail additional costs and additional losses. There is naturally no doubt about the economic efficiency of compressed air transmission when the field of application relates to a case in which, for example, in cleaning or drying processes, a tight means has to be used.

That’s how energy is transmitted with compressed air in many cases economically, the situation shifts considerably if a means succeeds to bring to use, which is a significantly more economical production permitted. This not only reduces the production costs of the pressure medium, but also the transmission costs (pipelines) can also be produced more cheaply, since it becomes possible to increase the voltage under which the pressure medium is passed on To increase the basis of more economical production. The same apply here Considerations as they are essentially in the voltage increase for the electrical Power transmission counted.

Accordingly, what is proposed according to the present invention is suitable new power transmission mainly to drive all reciprocating, in particular systems, machines and tools that work abruptly, d. H. for example for driving forge hammers, rammers, scissors, scrapers, drills, rammers, Impact chisels, vibrating machines, vibrating chutes, etc. Systems, machines and tools with moving back and forth are known to be found mainly on mines, Iron and steel works, - # Valzwerke and similar large companies; it will for example referred to the devices for turning _the sheets in Walnverken. A special The pneumatic power transmission means is also preferred the good speed adjustment through the tensioned means of acted upon motors. Accordingly, the proposed pneumatic power transmission means according to the present invention can be used wherever compressed air motors have been used successfully so far Companies are, mainly among other things, So in the mine where the electrical Long-distance power transmission due to the risk of sparks and ignition Weather is undesirable. The new generation process can also be considered there, where very large amounts of tensioned agent are required, for example all Spraying processes (paint spraying processes, metal spraying processes, etc.) and cleaning processes; Think, for example, of blowing out castings and combating them of conflagrations, in which the new process succeeds in eliminating the burning ones The rooms are completely clean of the oxygen-containing air and through the To displace inert gases that make up the fire gases of a deflagration combustion turbine exist. The list is in no way exhaustive; she should only have some illustrate particularly suitable use cases.

The fire gases of a deflagration combustion turbine lead naturally like all combustion gases a certain amount of carbon monoxide rides itself, but this is how it is it is low that, for example, the expanded gases released into the work rooms due to their strong. -Dilution does not cause any damage to health. will. However, if there are limited workspaces, such as in mines, to the Available, then there is easily the possibility of using more suitable Cleaning devices to remove the carbon monoxide content of the combustion gases or to bind the harmful chemical substances through catalysts. In this Case, the elimination is expediently carried out where the fire gases as possible have high temperature, d. H. immediately after leaving the deflagration turbine. Likewise, of course, the other undesirable constituents of the fire gases, preferably the acid anhydrides are removed, for example. by arranging in the way the scrubbing devices lying on the flue gases. Removal of such becomes useful Acid anhydrides made before the saturation temperature of the in the exhaust gases , contained water vapor is reached.

Mark the devices used to carry out the new procedure mainly through the arrangement of a deflagration combustion turbine, its exhaust gases the heat content is completely or almost withdrawn, unless the tension is just that Means should be applied under the high production temperatures. The withdrawal the heat content naturally takes place before the long-distance line of the power transmission means, whereby the extracted heat can be used, for example for preheating, steam generation and steam arrangement, is exploited. The deflagration internal combustion turbine can be used in a manner known per se drive the compressor required for their operation themselves. The Waste heat from the detonation combustion turbine can be used to drive the compressor. If the compressor delivers more air than is necessary to operate the internal combustion turbine system, so this excess air can also be used for power transmission. It can further the excess energy of the deflagration turbine system other energy-consuming machines, such as generators, pumps, etc., are released. The cooling heat of the internal combustion turbine can be used in a manner known per se to generate steam, the heat contained in the exhaust gases initially for steam overheating and on it can then be used to preheat the feed water. There is expediently the steam overheating in the superheating of the live steam and in a to this subsequent reheating at least once.

The drawing shows the exemplary embodiment of an implementation the system serving the process according to the invention. It denotes i the deflagration chambers the multi-chamber deflagration combustion turbine. In the deflagration chambers an ignitable mixture by introducing pressurized air via charge air valve 6a and formed by fuel via fuel inlet valve 5d. The ignitable mixture is ignited by means of the igniter, whereupon the combustion gases formed over the open nozzle valve 2a and the nozzles 3a the impeller q. the deflagration turbine apply. The exhaust gases collect in space 2 and after they are one have painted the carbon oxide removing catalyst 29 into the exhaust pipe 5 introduced; the back pressure prevailing in room 2 corresponds approximately to the pressure level, under which the fire gases are to be fed to the tapping points in the pipeline network. All deflagration chambers i are surrounded by pressure-resistant cooling jackets 3; as well the discharge housing 2 is encased in a pressure-resistant jacket q.a. A pressurized water pipe io appropriately supplies preheated pressurized water to the space between the jacket Absorption of the cooling heat is withdrawn via line 13. In front of the pressurized water tank 17 a pressure reducing valve 15 is arranged so that in the container 17 steam is formed entry. The steam formed is via line i8. those arranged in the exhaust pipe 5 Steam superheaters 19 and 20 supplied. The superheated steam withdrawn at 21 does first work in the high pressure steam turbine 22 and then, after another Reheating, fed at 23 via line 24 to the low-pressure turbine 25, to be released to condenser pressure. That precipitated in the condenser 26 Condensed water is disposed in a preheater 28, which is also located in the exhaust pipe 5 is, preheated and fed via line 27 to a storage container 9. A pressure pump 8 puts the withdrawn from the reservoir 9 water under pressure and leads it again via line io into the cold rooms of the deflagration combustion engine. aside from that The pressure pump 16 puts the water under pressure that is not in steam in container 17 was implemented, but the line OK via pump 16, line 1q., preheater 12 and line i i is closed. .

In the exhaust pipe 5 there are also washing devices 30 and 7 for removing the acid anhydrides. The washing device 7 is arranged in such a way that most of the acid anhydride is removed before the saturation temperature of the water vapor contained in the exhaust gases is reached; the washing device 3o serves to wash out the residues of acid anhydrides which could not be removed beforehand.

It can be seen that the system shown is a complete dissipation of the Heat content of the fire gases. The exhaust pipe 5 thus discharges approximately at the point 30 a completely harmless, inert pressurized gas, for example, which is available in the form of compressed air for remote power transmission.

It is in the essence of the invention that manifold modifications of the illustrated system can be taken without affecting the inventive concept something changes.

Claims (1)

PATENT CLAIMS: r. Process for obtaining a pressure medium which the type of compressed air used for remote power transmission, characterized in that that this means in detonation combustion turbine systems in the form of stressed fire gases is produced. z. Method according to claim i, characterized in that the fire gases the heat content upstream of the pipeline is wholly or partially withdrawn by utilizing it will.