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EP2912374B1 - Method for producing steam - Google Patents

Method for producing steam Download PDF

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Publication number
EP2912374B1
EP2912374B1 EP13824103.9A EP13824103A EP2912374B1 EP 2912374 B1 EP2912374 B1 EP 2912374B1 EP 13824103 A EP13824103 A EP 13824103A EP 2912374 B1 EP2912374 B1 EP 2912374B1
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EP
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Prior art keywords
combustion chamber
water
oxygen
water vapor
inlet
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EP13824103.9A
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German (de)
French (fr)
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EP2912374A1 (en
Inventor
Stefan Voss
Martin Still
Dimosthenis Trimis
Holger Venzke
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ThyssenKrupp Marine Systems GmbH
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ThyssenKrupp Marine Systems GmbH
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    • FMECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
    • F22STEAM GENERATION
    • F22BMETHODS OF STEAM GENERATION; STEAM BOILERS
    • F22B1/00Methods of steam generation characterised by form of heating method
    • F22B1/003Methods of steam generation characterised by form of heating method using combustion of hydrogen with oxygen

Definitions

  • the invention relates to a method for generating water vapor, are burned in the hydrogen and oxygen with the addition of liquid water in a combustion chamber. Furthermore, the invention relates to a device for carrying out this method and a submarine with such a device.
  • the adiabatic flame temperature is comparatively high in the stoichiometric combustion of hydrogen and oxygen. This can lead to a part of the water vapor generated during combustion dissociating again outside the hydrogen-oxygen flame to hydrogen and oxygen, whereby the hydrogen and oxygen molecules thus formed partly no longer participate in the combustion process.
  • the product gas produced during combustion then contains hydrogen and oxygen in addition to water vapor. Water vapor of the highest purity can be produced only with a complex post-treatment of the product gas, for example in the form of a catalytic afterburning.
  • high demands are placed on the materials or components used in the combustion chamber.
  • the outer wall of the combustion chamber in a complex manner to protect against the prevailing in the combustion chamber high temperature.
  • the system includes a hydrogen supply, an oxygen supply and a combustion chamber.
  • From the DE 102 43 250 A1 is a method and a steam generator for producing water vapor, in particular ultrapure water vapor, by reacting a stoichiometric mixture of a fuel, in particular hydrogen, and an oxidizer, in particular oxygen, and injecting water into the hot reaction gases, which are produced by a high purity of the Steam is known.
  • the object of the invention is to provide a method for producing superheated steam of highest purity by combustion of hydrogen and oxygen, in which the described problems of the previously known methods of this type do not occur. It is another object of the invention to provide an apparatus for performing this method.
  • hydrogen and oxygen are burned with the addition of water in a combustion chamber.
  • the hydrogen and the oxygen are expediently supplied in a stoichiometric ratio in the combustion process.
  • the hydrogen is introduced from the oxygen spatially separated into the combustion chamber.
  • the basic idea of the invention is to introduce liquid water in a common volume flow with the oxygen into the combustion chamber. Unlike previously customary, the liquid water is therefore not introduced in the post-combustion zone of the hydrogen-oxygen flame, but in the preheating and combustion zone of the combustion chamber together with the oxygen. Due to this introduction of the water into the combustion chamber, the adiabatic flame temperature in the combustion chamber is locally reduced compared to the previously customary combustion process management.
  • the reaction temperature in the combustion chamber in the inventive method is about 950 to 1050 ° C.
  • the outer wall of the combustion chamber and arranged in the combustion chamber components or component groups are exposed in the inventive method a significantly lower thermal load. This makes it possible, if appropriate, to arrange ignition devices and measuring sensors directly in the combustion chamber. Further advantageously, the reaction temperature is above the temperature at which it comes to chain termination reactions of a hydrogen-oxygen mixture. In this respect, a trouble-free process is guaranteed in this regard.
  • the method according to the invention it is provided to add additional liquid water to the combustion chamber on the output side of the steam generated in the combustion chamber.
  • the temperature control is typically carried out via the amount of the water vapor supplied to the liquid water, which also evaporates due to the temperature of the already existing water vapor.
  • the steam has a lower temperature than the water vapor present before the addition of the additional liquid water.
  • the reaction temperatures prevailing in the combustion chamber in the method according to the invention are comparatively low, it is preferably provided to cool the combustion chamber on its outer side so as to dissipate the heat absorbed by the outer wall of the combustion chamber.
  • the water to be evaporated is particularly advantageously used beforehand for cooling the outer wall of the combustion chamber. Ie.
  • water, which is led along to form a cooling flow on the outside of the combustion chamber then, after it has absorbed heat from the outer wall of the combustion chamber, passed in a common volume flow with the oxygen in the combustion chamber and / or the output side of the combustion chamber in the Combustion chamber generated water vapor added. Accordingly, the water before it is introduced together with the oxygen in the combustion chamber or the output side of the combustion chamber is added to the water vapor generated in the combustion chamber, advantageously already preheated.
  • the water is homogeneously mixed with the oxygen introduced into the combustion chamber.
  • the water supplied to the combustion chamber is atomized before being introduced into the combustion chamber by means of the oxygen stream.
  • the resulting oxygen-water mist is then introduced into the combustion chamber.
  • the atomization of the water causes an improvement in the heat exchange between the hydrogen-oxygen flame and the water and, consequently, an acceleration of the evaporation process of this water.
  • the inventive device for generating water vapor has a combustion chamber with a hydrogen inlet and an oxygen inlet.
  • the hydrogen inlet and the oxygen inlet preferably open at a distance from one another into the combustion chamber.
  • the oxygen inlet is connected on the input side via a lockable supply line to a water source.
  • a supply line leading from an oxygen source to the oxygen inlet another supply line coming from a water source is connected to the oxygen inlet.
  • a steam outlet is arranged on the combustion chamber.
  • this steam outlet opens on the output side of the combustion chamber into a mixing chamber, which also has a water inlet for liquid water.
  • a space into which the steam can directly flow from the combustion chamber where the water vapor is then mixed with further water vapor formed by evaporating liquid water, which is passed via the water inlet into the mixing chamber.
  • a controller may be provided, with which the introduced via the water inlet into the mixing chamber amount of water is controllable, which then also the temperature of the water vapor generated in the device according to the invention can be controlled.
  • the hydrogen inlet is arranged on the combustion chamber concentrically around the oxygen inlet.
  • the hydrogen inlet may be annular or, as is preferably provided, may be formed by a plurality of hydrogen inlet openings arranged annularly at a radial distance from the oxygen inlet therearound. This radial distance of the oxygen inlet from the hydrogen inlet, and preferably also a distance in the outflow direction of the oxygen inlet between the oxygen inlet and the hydrogen inlet advantageously prevent heat transfer from the hydrogen-oxygen flame to the oxygen inlet, so that the oxygen inlet is protected from excessive thermal load.
  • an inlet for introducing the water vapor coming from the combustion chamber and a further inlet for introducing the additional liquid water can be formed on the mixing chamber.
  • the steam outlet of the combustion chamber also forms the water inlet of the mixing chamber.
  • the mixing chamber preferably has only one flow inlet, which is formed by the steam outlet of the combustion chamber, wherein in the flow path through this steam outlet, a supply line coming from the water source flows through which liquid water can flow into the steam outlet and from there into the mixing chamber.
  • the steam outlet is designed such that the water supplied to it is atomized in it.
  • the steam outlet is a nozzle, wherein it is preferably provided that the steam outlet is designed as a critical nozzle.
  • the use of a critical nozzle as the steam outlet of the combustion chamber has the advantage that it can be used to realize a constant flow of steam into the mixing chamber.
  • Another advantage of using the critical nozzle As the steam outlet of the combustion chamber or as a water vapor inlet of the mixing chamber is to be seen in that the combustion chamber is thereby decoupled from pressure fluctuations, which may occur in the device according to the invention downstream devices or systems.
  • the mixing chamber is preferably a porous material filled.
  • This porous material may advantageously be a wire mesh, which forms a comparatively large porous and thus gas-permeable surface due to the meshes formed therein.
  • At least one flow-connected with a water source cooling water channel is expediently formed on the outer wall of the combustion chamber.
  • this cooling water channel is connected downstream with the oxygen inlet of the combustion chamber and / or with the water vapor outlet of the combustion chamber.
  • the cooling water channel in this embodiment forms part of the supply line from the water source to the oxygen inlet of the combustion chamber and a part of the supply line from the water source to the water vapor outlet of the combustion chamber and the water vapor inlet of the mixing chamber.
  • thermal insulation materials in particular thermal insulation panels, can be arranged in the combustion chamber.
  • the heat absorbed by these thermal insulation panels can then be removed from the combustion chamber via the at least one cooling water channel arranged on the outer wall of the combustion chamber.
  • the device according to the invention With the method according to the invention for producing steam and with the device according to the invention for this purpose, it is possible to produce superheated steam at low temperature near the saturated steam line. Superheated steam at this temperature range will be used to regenerate the submarine CO2 binders used to bind the CO2 contained in the air inside the submarine. Therefore, the device according to the invention is also particularly suitable for use in a submarine. In this respect, the invention also relates to a submarine, which has a device for generating water vapor with the features described above.
  • FIG. 1 illustrated apparatus for generating water vapor has a combustion chamber 2, in which gaseous hydrogen H 2 (g) and gaseous oxygen O 2 (g) are burned, wherein as product gas steam H 2 O (g) is formed.
  • the combustion chamber 2 is formed by a substantially cylindrical housing 4, whose open end faces are closed by end plates 6 and 8.
  • an oxygen inlet and a hydrogen inlet are formed ( Fig. 3 ).
  • the oxygen inlet is formed by a nozzle 10 which is centrally located on the end plate 6.
  • the hydrogen inlet into the combustion chamber 2 form twelve hydrogen inlet openings 12, which are formed at a radial distance from the nozzle 10 in an annular manner around it.
  • a conical recess 14 is formed on the end plate 6. At the tapered end of this recess 14, the nozzle 10 opens.
  • liquid water H 2 O (fl) is also introduced into the combustion chamber 2 via the nozzle 10 as the oxygen inlet.
  • a connection 16 for connecting a supply line coming from an oxygen source and a connection 18 for connecting a supply line coming from a water source are formed on the inlet side of the nozzle 10.
  • the water source and the supply lines has been omitted for reasons of clarity.
  • the housing 4 and the end plate 6 are clad on their inner side facing the combustion chamber 2 with thermal insulation panels 20. Through the end plate 6, an igniter 22 of an electric ignition device is guided into the interior of the combustion chamber 2, which serves there for generating a hydrogen-oxygen flame.
  • a water vapor outlet 24 is arranged centrally.
  • This steam outlet 24 is formed by a critical nozzle.
  • a plurality of relief bores 26 are arranged on the end plate 8.
  • the steam inlet 24 opens into a mixing chamber 28.
  • This mixing chamber 28 is formed by a substantially cylindrical housing 30, which is flanged to the end plate 8 on the side facing away from the combustion chamber 2 side.
  • An outlet 32 is formed on the housing 30 at an end remote from the end plate 8.
  • In the mixing chamber 28 are in the flow path of the hydrogen outlet 24, which forms a hydrogen inlet into the mixing chamber 28, and the outlet 32 in succession a plurality of segments 34 made of a porous material, such. B. wire knit arranged.
  • the groove 36 serves to receive a cooling water channel in the form of a line 38.
  • the line 38 is connected to a water source, not shown in the drawing. Downstream of the conduit 38 there is also a flow connection, not shown in the drawing, between the conduit 38 and the nozzle 10 and between the conduit 38 and the water vapor outlet 24 formed on the end plate 8, a portion of this conduit connection being formed by a bore 40 formed on the end plate 8 ( Fig. 4 ) is formed, which extends from the outside of the end plate 8 radially inwardly and opens into the steam outlet 24.
  • the combustion chamber 2 is cooled by means of water flowing through the line 38 H 2 O (fl) .
  • Part of this water H 2 O (fl) is supplied to the oxygen stream in the nozzle 10, from where it enters the combustion chamber 2 atomized with the oxygen O 2 (g) .
  • the water evaporates H 2 O (fl) to additional water vapor H 2 O (g) .
  • the generated water vapor H 2 O (g) leaves the mixing chamber 28 through the outlet 32, where it is available for a variety of applications. Previously, it is homogenized in the mixing chamber 28 with respect to its temperature by flowing through the porous segments 34 located in the mixing chamber 28.

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  • Engineering & Computer Science (AREA)
  • Mechanical Engineering (AREA)
  • Chemical & Material Sciences (AREA)
  • Combustion & Propulsion (AREA)
  • Life Sciences & Earth Sciences (AREA)
  • Sustainable Development (AREA)
  • Sustainable Energy (AREA)
  • Physics & Mathematics (AREA)
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  • General Engineering & Computer Science (AREA)
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Description

Die Erfindung betrifft ein Verfahren zur Erzeugung von Wasserdampf, bei dem Wasserstoff und Sauerstoff unter Zugabe von flüssigem Wasser in einer Brennkammer verbrannt werden. Ferner betrifft die Erfindung eine Vorrichtung zur Durchführung dieses Verfahrens sowie ein Unterseeboot mit einer solchen Vorrichtung.The invention relates to a method for generating water vapor, are burned in the hydrogen and oxygen with the addition of liquid water in a combustion chamber. Furthermore, the invention relates to a device for carrying out this method and a submarine with such a device.

Es ist allgemein bekannt, Wasserdampf durch Verbrennung von Wasserstoff und Sauerstoff zu erzeugen. Zum Stand der Technik gehört es auch, zur Erzeugung zusätzlichen Wasserdampfs in die Brennkammer, in der die Verbrennung des Wasserstoffs mit dem Sauerstoff abläuft, Wasser außerhalb der eigentlichen Verbrennungszone einzubringen und so dort zu verdampfen.It is well known to generate water vapor by combustion of hydrogen and oxygen. It is also part of the state of the art to introduce water outside the actual combustion zone and thus vaporize it in order to generate additional water vapor into the combustion chamber in which the combustion of the hydrogen with the oxygen takes place.

Die adiabate Flammentemperatur ist bei der stöchiometrischen Verbrennung von Wasserstoff und Sauerstoff vergleichsweise hoch. Dies kann dazu führen, dass ein Teil des bei der Verbrennung erzeugten Wasserdampfs außerhalb der Wasserstoff-Sauerstoff-Flamme wieder zu Wasserstoff und Sauerstoff dissoziiert, wobei die so gebildeten Wasserstoff- und Sauerstoffmoleküle teilweise nicht mehr am Verbrennungsvorgang teilnehmen. Das bei der Verbrennung entstehende Produktgas enthält dann neben Wasserdampf auch Wasserstoff und Sauerstoff. Wasserdampf höchster Reinheit lässt sich nur mit einer aufwändigen Nachbehandlung des Produktgases, beispielsweise in Form einer katalytischen Nachverbrennung erzeugen. Des Weiteren sind mit der hohen adiabaten Flammentemperatur bei der Verbrennung von Wasserstoff und Sauerstoff hohe Anforderungen an die in der Brennkammer eingesetzten Materialien bzw. Bauteile verbunden. So ist die Außenwandung der Brennkammer in aufwändiger Weise vor der in der Brennkammer herrschenden hohen Temperatur zu schützen. Eine direkte Anordnung von Zündeinrichtungen und Messsensoren in der Brennkammer ist aufgrund der hohen Temperatur in der Brennkammer in der Regel nicht möglich. Auch das Einbringen des Wassers in die Brennkammer erweist sich bei der bislang bekannten Vorgehensweise als problematisch. So kann das in die Brennkammer eingebrachte Wasser bei dem in der Brennkammer ablaufenden Oxidationsprozess aufgrund einer damit verbundenen Herabsetzung der Flammentemperatur zu Kettenabbruchreaktionen führen.The adiabatic flame temperature is comparatively high in the stoichiometric combustion of hydrogen and oxygen. This can lead to a part of the water vapor generated during combustion dissociating again outside the hydrogen-oxygen flame to hydrogen and oxygen, whereby the hydrogen and oxygen molecules thus formed partly no longer participate in the combustion process. The product gas produced during combustion then contains hydrogen and oxygen in addition to water vapor. Water vapor of the highest purity can be produced only with a complex post-treatment of the product gas, for example in the form of a catalytic afterburning. Furthermore, with the high adiabatic flame temperature during the combustion of hydrogen and oxygen, high demands are placed on the materials or components used in the combustion chamber. Thus, the outer wall of the combustion chamber in a complex manner to protect against the prevailing in the combustion chamber high temperature. A direct arrangement of ignition devices and measuring sensors in the combustion chamber is not possible due to the high temperature in the combustion chamber in the rule. The introduction of the water into the combustion chamber proves to be problematic in the previously known approach. Thus, the water introduced into the combustion chamber can lead to chain termination reactions in the oxidation process taking place in the combustion chamber due to a concomitant reduction in the flame temperature.

Aus der US 7 128 624 B1 ist ein Antriebssystem für ein Unterwasserfahrzeug bekannt. Das System enthält eine Wasserstoffversorgung ein eine Sauerstoffversorgung sowie eine Brennkammer.From the US Pat. No. 7,128,624 B1 a propulsion system for an underwater vehicle is known. The system includes a hydrogen supply, an oxygen supply and a combustion chamber.

Aus der DE 102 43 250 A1 ist ein Verfahren und einen Dampferzeuger zum Erzeugen von Wasserdampf, insbesondere Reinstwasserdampf, durch Reaktion eines stöchiometrischen Gemischs aus einem Brennstoff, insbesondere Wasserstoff, und einem Oxidator, insbesondere Sauerstoff, und Eindüsen von Wasser in die heißen Reaktionsgase, das sich durch eine hohe Reinheit des erzeugten Wasserdampfes auszeichnet, bekannt.From the DE 102 43 250 A1 is a method and a steam generator for producing water vapor, in particular ultrapure water vapor, by reacting a stoichiometric mixture of a fuel, in particular hydrogen, and an oxidizer, in particular oxygen, and injecting water into the hot reaction gases, which are produced by a high purity of the Steam is known.

Aus der EP 0 197 555 A2 ist ein Verfahren zur Erzeugung von Wasserdampf in einem Dampferzeuger bekannt, bei dem man in einer Heißgasreaktionskammer Wasserstoff und Sauerstoff zu Wasserdampf reagieren läßt, bei dem man in der Wand der Heißgasreaktionskammer Wasser erwärmt und bei dem man das erwärmte Wasser in die heißen Reaktionsgase einspritzt.From the EP 0 197 555 A2 is a method for producing steam in a steam generator is known, in which one reacts in a hot gas reaction chamber hydrogen and oxygen to steam, in which one heats water in the wall of the hot gas reaction chamber and in which one injects the heated water into the hot reaction gases.

Die Aufgabe der Erfindung besteht darin, ein Verfahren zur Erzeugung von überhitztem Wasserdampf höchster Reinheit durch Verbrennung von Wasserstoff und Sauerstoff zur Verfügung zu stellen, bei dem die geschilderten Probleme der bislang bekannten Verfahren dieser Art nicht auftreten. Ferner ist es Aufgabe der Erfindung, eine Vorrichtung zur Durchführung dieses Verfahrens zu schaffen.The object of the invention is to provide a method for producing superheated steam of highest purity by combustion of hydrogen and oxygen, in which the described problems of the previously known methods of this type do not occur. It is another object of the invention to provide an apparatus for performing this method.

Gelöst wird diese Aufgabe durch ein Verfahren zur Erzeugung von Wasserdampf mit den in Anspruch 1 angegebenen Merkmalen und mit einer Vorrichtung zur Erzeugung von Wasserdampf mit den in Anspruch 6 angegebenen Merkmalen. Vorteilhafte Weiterbildungen des Verfahrens und der Vorrichtung ergeben sich aus den Unteransprüchen, der nachfolgenden Beschreibung sowie der Zeichnung. Hierbei können gemäß der Erfindung die in den Unteransprüchen 2 bis 5 angegebenen Merkmale jeweils für sich, aber auch in technisch sinnvoller Kombination das Verfahren nach Anspruch 1 und die in den Unteransprüchen 7 bis 12 angegebenen Merkmale jeweils alleine oder miteinander kombiniert die Vorrichtung nach Anspruch 6 weiter ausgestalten.This object is achieved by a method for generating water vapor having the features specified in claim 1 and with a device for generating water vapor having the features specified in claim 6. Advantageous developments of the method and the device will become apparent from the dependent claims, the following description and the drawings. Here, according to the invention, the specified in the dependent claims 2 to 5 features each alone, but also in a technically meaningful combination, the method of claim 1 and the features specified in the dependent claims 7 to 12 features alone or combined with each other, the device of claim 6 on embellish.

Bei dem erfindungsgemäßen Verfahren zur Erzeugung von Wasserdampf werden Wasserstoff und Sauerstoff unter Zugabe von Wasser in einer Brennkammer verbrannt. Der Wasserstoff und der Sauerstoff werden im Verbrennungsprozess zweckmäßigerweise in einem stöchiometrischen Mengenverhältnis zugeführt. Bevorzugt wird der Wasserstoff von dem Sauerstoff räumlich getrennt in die Brennkammer eingebracht.In the method according to the invention for producing water vapor, hydrogen and oxygen are burned with the addition of water in a combustion chamber. The hydrogen and the oxygen are expediently supplied in a stoichiometric ratio in the combustion process. Preferably, the hydrogen is introduced from the oxygen spatially separated into the combustion chamber.

Die Grundidee der Erfindung ist es, flüssiges Wasser in einem gemeinsamen Volumenstrom mit dem Sauerstoff in die Brennkammer einzuleiten. Anders als bislang üblich wird das flüssige Wasser demnach nicht in der Nachverbrennungszone der Wasserstoff-Sauerstoff-Flamme, sondern in der Vorwärm- und Verbrennungszone der Brennkammer zusammen mit dem Sauerstoff eingebracht. Aufgrund dieser Einleitung des Wassers in die Brennkammer wird die adiabate Flammentemperatur in der Brennkammer gegenüber der bislang üblichen Verbrennungsprozessführung lokal herabgesetzt. So beträgt die Reaktionstemperatur in der Brennkammer bei dem erfindungsgemäßen Verfahren etwa 950 bis 1.050 ° C. Vorteilhafterweise findet bei dieser Reaktionstemperatur keine Dissoziation des bei der Verbrennung erzeugten Wasserdampfs statt, sodass bei dem erfindungsgemäßen Verfahren keine freien Wasserstoff- und Sauerstoffmoleküle entstehen und somit Wasserdampf höchster Reinheit erzeugt werden kann. Die Außenwandung der Brennkammer sowie die in der Brennkammer angeordneten Bauteile bzw. Bauteilgruppen sind bei dem erfindungsgemäßen Verfahren einer deutlich geringeren thermischen Belastung ausgesetzt. Dies ermöglicht es, Zündeinrichtungen und Messsensoren gegebenenfalls direkt in der Brennkammer anzuordnen. Weiter vorteilhaft liegt die Reaktionstemperatur oberhalb der Temperatur, in der es zu Kettenabbruchreaktionen eines Wasserstoff-Sauerstoff-Gemisches kommt. Insofern ist auch in dieser Hinsicht eine störungsfreie Prozessführung gewährleistet.The basic idea of the invention is to introduce liquid water in a common volume flow with the oxygen into the combustion chamber. Unlike previously customary, the liquid water is therefore not introduced in the post-combustion zone of the hydrogen-oxygen flame, but in the preheating and combustion zone of the combustion chamber together with the oxygen. Due to this introduction of the water into the combustion chamber, the adiabatic flame temperature in the combustion chamber is locally reduced compared to the previously customary combustion process management. Thus, the reaction temperature in the combustion chamber in the inventive method is about 950 to 1050 ° C. Advantageously, takes place at this reaction temperature no dissociation of the water vapor generated during combustion, so that no free hydrogen and oxygen molecules are formed in the inventive method and thus water vapor of highest purity can be generated. The outer wall of the combustion chamber and arranged in the combustion chamber components or component groups are exposed in the inventive method a significantly lower thermal load. This makes it possible, if appropriate, to arrange ignition devices and measuring sensors directly in the combustion chamber. Further advantageously, the reaction temperature is above the temperature at which it comes to chain termination reactions of a hydrogen-oxygen mixture. In this respect, a trouble-free process is guaranteed in this regard.

In vorteilhafter Weiterbildung des erfindungsgemäßen Verfahrens ist vorgesehen, dem in der Brennkammer erzeugten Wasserdampf ausgangsseitig der Brennkammer zusätzliches flüssiges Wasser hinzuzufügen. Mit dieser Maßnahme wird die Möglichkeit geschaffen, die Wasserdampfmenge und vor allem die Temperatur des erzeugten Wasserdampfes einzustellen. Die Temperatursteuerung erfolgt dabei typischerweise über die Menge des dem Wasserdampf zugeführten flüssigen Wassers, das aufgrund der Temperatur des bereits vorhandenen Wasserdampfs ebenfalls verdampft. Durch die Zugabe des zusätzlichen Wassers weist der Wasserdampf gegenüber dem vor der Zugabe des zusätzlichen flüssigen Wassers vorhandenen Wasserdampf eine geringere Temperatur auf. Anders als bei den bislang bekannten Verfahren zur Wasserdampferzeugung durch die Verbrennung von Wasserstoff und Sauerstoff lassen sich auf diese Weise Wasserdampftemperaturen verwirklichen, die in einem Bereich unterhalb von 200 ° C liegen.In an advantageous development of the method according to the invention, it is provided to add additional liquid water to the combustion chamber on the output side of the steam generated in the combustion chamber. With this measure, the possibility is created to adjust the amount of steam and especially the temperature of the water vapor generated. The temperature control is typically carried out via the amount of the water vapor supplied to the liquid water, which also evaporates due to the temperature of the already existing water vapor. As a result of the addition of the additional water, the steam has a lower temperature than the water vapor present before the addition of the additional liquid water. In contrast to the hitherto known processes for the generation of steam by the combustion of hydrogen and oxygen, it is thus possible to realize steam temperatures which lie in a range below 200 ° C.

Obwohl die bei dem erfindungsgemäßen Verfahren in der Brennkammer herrschenden Reaktionstemperaturen vergleichsweise niedrig sind, ist bevorzugt vorgesehen, die Brennkammer an ihrer Außenseite zu kühlen, um so die von der Außenwandung der Brennkammer aufgenommene Wärme abzuführen. Besonders vorteilhaft wird hierbei das zu verdampfende Wasser zuvor zur Kühlung der Außenwandung der Brennkammer verwendet. D. h. bevorzugt wird Wasser, welches zur Bildung eines Kühlstroms an der Außenseite der Brennkammer entlanggeführt wird, anschließend, nachdem es Wärme von der Außenwandung der Brennkammer aufgenommen hat, in einem gemeinsamen Volumenstrom mit dem Sauerstoff in die Brennkammer geleitet und/oder ausgangsseitig der Brennkammer dem in der Brennkammer erzeugten Wasserdampf hinzugefügt. Demnach ist das Wasser, bevor es zusammen mit dem Sauerstoff in die Brennkammer eingeleitet wird bzw. dem in der Brennkammer erzeugten Wasserdampf ausgangsseitig der Brennkammer hinzugefügt wird, vorteilhafterweise bereits vorgewärmt.Although the reaction temperatures prevailing in the combustion chamber in the method according to the invention are comparatively low, it is preferably provided to cool the combustion chamber on its outer side so as to dissipate the heat absorbed by the outer wall of the combustion chamber. In this case, the water to be evaporated is particularly advantageously used beforehand for cooling the outer wall of the combustion chamber. Ie. Preferably, water, which is led along to form a cooling flow on the outside of the combustion chamber, then, after it has absorbed heat from the outer wall of the combustion chamber, passed in a common volume flow with the oxygen in the combustion chamber and / or the output side of the combustion chamber in the Combustion chamber generated water vapor added. Accordingly, the water before it is introduced together with the oxygen in the combustion chamber or the output side of the combustion chamber is added to the water vapor generated in the combustion chamber, advantageously already preheated.

Zweckmäßigerweise wird das Wasser mit dem Sauerstoff homogen vermengt in die Brennkammer eingeleitet. So ist bevorzugt vorgesehen, dass das der Brennkammer zugeführte Wasser vor Einleitung in die Brennkammer mittels des Sauerstoffstroms zerstäubt wird. Der dabei entstehende Sauerstoff-Wasser-Nebel wird dann in die Brennkammer eingeleitet. Die Zerstäubung des Wassers bewirkt eine Verbesserung des Wärmeaustausches zwischen der Wasserstoff-Sauerstoff-Flamme und dem Wasser und damit einhergehend eine Beschleunigung des Verdampfungsprozesses dieses Wassers.Conveniently, the water is homogeneously mixed with the oxygen introduced into the combustion chamber. Thus, it is preferably provided that the water supplied to the combustion chamber is atomized before being introduced into the combustion chamber by means of the oxygen stream. The resulting oxygen-water mist is then introduced into the combustion chamber. The atomization of the water causes an improvement in the heat exchange between the hydrogen-oxygen flame and the water and, consequently, an acceleration of the evaporation process of this water.

Mit der Zielsetzung, den Wärmeaustausch zwischen dem in der Brennkammer erzeugten Wasserdampf und dem diesem Wasserdampf ausgangsseitig der Brennkammer hinzugefügten flüssigen Wasser zu verbessern und eine schnelle Verdampfung des flüssigen Wassers zu bewirken, ist in ähnlicher Weise vorgesehen, vorzugsweise auch das dem in der Brennkammer erzeugten Wasserdampf hinzugefügte flüssige Wasser zu zerstäuben, wobei hierzu der Wasserdampfstrom als Treibgas verwendet wird.With the aim of improving the heat exchange between the water vapor generated in the combustion chamber and the water added to the output side of the combustion chamber liquid water and to effect a rapid evaporation of the liquid water is provided in a similar manner, preferably also the water vapor generated in the combustion chamber To atomize added liquid water, for which purpose the steam stream is used as propellant gas.

Die erfindungsgemäße Vorrichtung zur Erzeugung von Wasserdampf weist eine Brennkammer mit einem Wasserstoffeinlass und einem Sauerstoffeinlass auf. Der Wasserstoffeinlass und der Sauerstoffeinlass münden bevorzugt voneinander beabstandet in die Brennkammer. Um in die Brennkammer flüssiges Wasser in einem gemeinsamen Volumenstrom mit dem Sauerstoff einleiten zu können, ist der Sauerstoffeinlass eingangsseitig über eine absperrbare Zufuhrleitung mit einer Wasserquelle verbunden. D. h., neben einer von einer Sauerstoffquelle zu dem Sauerstoffeinlass führenden Zuführleitung ist an dem Sauerstoffeinlass eine weitere, von einer Wasserquelle kommende Zuführleitung angeschlossen.The inventive device for generating water vapor has a combustion chamber with a hydrogen inlet and an oxygen inlet. The hydrogen inlet and the oxygen inlet preferably open at a distance from one another into the combustion chamber. To go in the combustion chamber to be able to introduce liquid water in a common volume flow with the oxygen, the oxygen inlet is connected on the input side via a lockable supply line to a water source. In other words, besides a supply line leading from an oxygen source to the oxygen inlet, another supply line coming from a water source is connected to the oxygen inlet.

Zur Ableitung des durch die Verbrennung des Wasserstoffs mit dem Sauerstoff und durch Verdampfung des flüssigen Wassers erzeugten Wasserdampfs ist an der Brennkammer ein Wasserdampfauslass angeordnet. Bevorzugt mündet dieser Wasserdampfauslass ausgangsseitig der Brennkammer in eine Mischkammer, welche auch einen Wassereinlass für flüssiges Wasser aufweist. Demnach ist abströmseitig der Brennkammer ein Raum angeordnet, in den der Wasserdampf von der Brennkammer direkt überströmen kann, wo der Wasserdampf dann mit weiterem Wasserdampf vermischt wird, der von verdampfendem flüssigen Wasser gebildet wird, welches über den Wassereinlass in die Mischkammer geleitet wird. Zweckmäßigerweise kann eine Steuerung vorgesehen sein, mit der die über den Wassereinlass in die Mischkammer eingeleitete Wassermenge steuerbar ist, wodurch sich dann auch die Temperatur des in der erfindungsgemäßen Vorrichtung erzeugten Wasserdampfs steuern lässt.To derive the water vapor generated by the combustion of the hydrogen with the oxygen and by evaporation of the liquid water, a steam outlet is arranged on the combustion chamber. Preferably, this steam outlet opens on the output side of the combustion chamber into a mixing chamber, which also has a water inlet for liquid water. Accordingly, downstream of the combustion chamber is arranged a space into which the steam can directly flow from the combustion chamber, where the water vapor is then mixed with further water vapor formed by evaporating liquid water, which is passed via the water inlet into the mixing chamber. Conveniently, a controller may be provided, with which the introduced via the water inlet into the mixing chamber amount of water is controllable, which then also the temperature of the water vapor generated in the device according to the invention can be controlled.

Gemäß einer weiteren vorteilhaften Ausgestaltung der Erfindung ist der Wasserstoffeinlass an der Brennkammer konzentrisch um den Sauerstoffeinlass herum angeordnet. Hierbei kann der Wasserstoffeinlass ringförmig ausgebildet sein oder, wie es bevorzugt vorgesehen ist, von einer Vielzahl von Wasserstoffeinlassöffnungen gebildet werden, die ringförmig mit radialem Abstand zu dem Sauerstoffeinlass um diesen herum angeordnet sind. Dieser radiale Abstand des Sauerstoffeinlasses von dem Wasserstoffeinlass sowie vorzugsweise auch ein Abstand in Ausströmrichtung des Sauerstoffeinlasses zwischen dem Sauerstoffeinlass und dem Wasserstoffeinlass verhindern vorteilhaft einen Wärmeübergang von der Wasserstoff-Sauerstoff-Flamme auf den Sauerstoffeinlass, sodass der Sauerstoffeinlass vor einer übermäßigen thermischen Belastung geschützt ist.According to a further advantageous embodiment of the invention, the hydrogen inlet is arranged on the combustion chamber concentrically around the oxygen inlet. Here, the hydrogen inlet may be annular or, as is preferably provided, may be formed by a plurality of hydrogen inlet openings arranged annularly at a radial distance from the oxygen inlet therearound. This radial distance of the oxygen inlet from the hydrogen inlet, and preferably also a distance in the outflow direction of the oxygen inlet between the oxygen inlet and the hydrogen inlet advantageously prevent heat transfer from the hydrogen-oxygen flame to the oxygen inlet, so that the oxygen inlet is protected from excessive thermal load.

Prinzipiell können an der Mischkammer ein Einlass zur Einleitung des von der Brennkammer kommenden Wasserdampfs und ein weiterer Einlass zur Einleitung des zusätzlichen flüssigen Wassers ausgebildet sein. Bevorzugt ist allerdings vorgesehen, dass der Wasserdampfauslass der Brennkammer auch den Wassereinlass der Mischkammer bildet. Dementsprechend weist die Mischkammer vorzugsweise lediglich einen Strömungseinlass auf, welcher von dem Wasserdampfauslass der Brennkammer gebildet wird, wobei in dem Strömungsweg durch diesen Wasserdampfauslass eine von der Wasserquelle kommende Zuführleitung mündet, über die flüssiges Wasser in den Wasserdampfauslass und von dort in die Mischkammer strömen kann.In principle, an inlet for introducing the water vapor coming from the combustion chamber and a further inlet for introducing the additional liquid water can be formed on the mixing chamber. Preferably, however, it is provided that the steam outlet of the combustion chamber also forms the water inlet of the mixing chamber. Accordingly, the mixing chamber preferably has only one flow inlet, which is formed by the steam outlet of the combustion chamber, wherein in the flow path through this steam outlet, a supply line coming from the water source flows through which liquid water can flow into the steam outlet and from there into the mixing chamber.

Zweckmäßigerweise ist der Wasserdampfauslass derart ausgebildet, dass das ihm zugeführte Wasser in ihm zerstäubt wird. Vorteilhaft handelt es sich daher bei dem Wasserdampfauslass um eine Düse, wobei bevorzugt vorgesehen ist, dass der Wasserdampfauslass als eine kritische Düse ausgebildet ist. Die Verwendung einer kritischen Düse als Wasserdampfauslass der Brennkammer hat den Vorteil, dass sich mit dieser ein konstanter Wasserdampfstrom in die Mischkammer verwirklichen lässt. Ein weiterer Vorteil der Verwendung der kritischen Düse als Wasserdampfauslass der Brennkammer bzw. als Wasserdampfeinlass der Mischkammer ist darin zu sehen, dass die Brennkammer hierdurch von Druckschwankungen, die gegebenenfalls in der erfindungsgemäßen Vorrichtung nachgeschalteten Vorrichtungen bzw. Anlagen auftreten können, entkoppelt wird.Conveniently, the steam outlet is designed such that the water supplied to it is atomized in it. Advantageously, therefore, the steam outlet is a nozzle, wherein it is preferably provided that the steam outlet is designed as a critical nozzle. The use of a critical nozzle as the steam outlet of the combustion chamber has the advantage that it can be used to realize a constant flow of steam into the mixing chamber. Another advantage of using the critical nozzle As the steam outlet of the combustion chamber or as a water vapor inlet of the mixing chamber is to be seen in that the combustion chamber is thereby decoupled from pressure fluctuations, which may occur in the device according to the invention downstream devices or systems.

Zur Unterstützung des Verdampfungsprozesses des ausgangsseitig der Brennkammer dem dort erzeugten Wasserdampf hinzugefügten flüssigen Wassers sowie zur Unterstützung der Vermischung des in der Brennkammer erzeugten Wasserdampfs mit dem in der Mischkammer erzeugten Wasserdampf und zur Verhinderung lokaler Temperaturunterschiede in der Mischkammer, ist die Mischkammer vorzugsweise mit einem porösen Material gefüllt. Bei diesem porösen Material kann es sich vorteilhaft um ein Drahtgestrick handeln, welches aufgrund der darin ausgebildeten Maschen eine vergleichsweise große poröse und somit gasdurchlässige Oberfläche bildet.In order to assist the evaporation process of the liquid side water added to the output side of the combustion chamber and to assist in mixing the water vapor generated in the combustion chamber with the water vapor generated in the mixing chamber and to prevent local temperature differences in the mixing chamber, the mixing chamber is preferably a porous material filled. This porous material may advantageously be a wire mesh, which forms a comparatively large porous and thus gas-permeable surface due to the meshes formed therein.

Um die Außenwandung der Brennkammer während der darin ablaufenden Verbrennung von Wasserstoff und Sauerstoff vor einer zu großen Wärmebeanspruchung zu schützen, ist zweckmäßigerweise an der Außenwandung der Brennkammer zumindest ein mit einer Wasserquelle strömungsverbundener Kühlwasserkanal ausgebildet. Besonders vorteilhaft ist dieser Kühlwasserkanal abströmseitig mit dem Sauerstoffeinlass der Brennkammer und/oder mit dem Wasserdampfauslass der Brennkammer strömungsverbunden. Insofern bildet der Kühlwasserkanal bei dieser Ausgestaltung einen Teil der Zuführleitung von der Wasserquelle zu dem Sauerstoffeinlass der Brennkammer und einen Teil der Zuführleitung von der Wasserquelle zu dem Wasserdampfauslass der Brennkammer bzw. dem Wasserdampfeinlass der Mischkammer.In order to protect the outer wall of the combustion chamber during the running therein of combustion of hydrogen and oxygen from excessive heat stress, at least one flow-connected with a water source cooling water channel is expediently formed on the outer wall of the combustion chamber. Particularly advantageously, this cooling water channel is connected downstream with the oxygen inlet of the combustion chamber and / or with the water vapor outlet of the combustion chamber. In this respect, the cooling water channel in this embodiment forms part of the supply line from the water source to the oxygen inlet of the combustion chamber and a part of the supply line from the water source to the water vapor outlet of the combustion chamber and the water vapor inlet of the mixing chamber.

Als weitere vorteilhafte Maßnahme zum Schutz der Außenwandung der Brennkammer sowie zum Schutz deren Sauerstoffeinlasses und Wasserstoffeinlasses können in der Brennkammer Wärmedämmstoffe, insbesondere Wärmedämmplatten angeordnet sein. Die von diesen Wärmedämmplatten aufgenommene Wärme kann dann über den zumindest einen an der Außenwandung der Brennkammer angeordneten Kühlwasserkanal von der Brennkammer abgeführt werden.As a further advantageous measure for protecting the outer wall of the combustion chamber and for protecting the oxygen inlet and the hydrogen inlet, thermal insulation materials, in particular thermal insulation panels, can be arranged in the combustion chamber. The heat absorbed by these thermal insulation panels can then be removed from the combustion chamber via the at least one cooling water channel arranged on the outer wall of the combustion chamber.

Mit dem erfindungsgemäßen Verfahren zur Erzeugung von Wasserdampf und mit der erfindungsgemäßen Vorrichtung hierfür ist es möglich, überhitzten Wasserdampf mit geringer Temperatur nahe der Sattdampflinie zu erzeugen. Überhitzter Wasserdampf in diesem Temperaturbereich wird zum Regenerieren der in Unterseebooten vorgesehenen CO2-Bindeeinrichtungen, die dort zum Binden des in der Luft im Inneren des Unterseeboots enthaltenen CO2 dienen, eingesetzt. Daher eignet sich die erfindungsgemäße Vorrichtung auch in besonderem Maße zum Einsatz in einem Unterseeboot. Insofern betrifft die Erfindung auch ein Unterseeboot, welches eine Vorrichtung zur Erzeugung von Wasserdampf mit den oben beschriebenen Merkmalen aufweist.With the method according to the invention for producing steam and with the device according to the invention for this purpose, it is possible to produce superheated steam at low temperature near the saturated steam line. Superheated steam at this temperature range will be used to regenerate the submarine CO2 binders used to bind the CO2 contained in the air inside the submarine. Therefore, the device according to the invention is also particularly suitable for use in a submarine. In this respect, the invention also relates to a submarine, which has a device for generating water vapor with the features described above.

Nachfolgend ist die Erfindung anhand eines in der Zeichnung dargestellten Ausführungsbeispiels näher erläutert. In der Zeichnung zeigt:

Fig. 1
schematisch sehr stark vereinfacht eine Vorrichtung zur Erzeugung von Wasserdampf,
Fig.2
in einem Längsschnitt eine Ausgestaltung der Vorrichtung nach Fig. 1,
Fig. 3
eine Einzelheit A aus Fig. 1,
Fig. 4
eine Einzelheit B aus Fig. 1 in einem Halbschnitt und
Fig. 5
in einer Prinzipdarstellung den Ablauf eines Verfahrens zur Erzeugung von Wasserdampf.
The invention is explained in more detail with reference to an embodiment shown in the drawing. In the drawing shows:
Fig. 1
schematically very simplified a device for generating water vapor,
Fig.2
in a longitudinal section an embodiment of the device according to Fig. 1 .
Fig. 3
a detail A from Fig. 1 .
Fig. 4
a detail B off Fig. 1 in a half cut and
Fig. 5
in a schematic representation of the sequence of a method for generating water vapor.

Die in Fig. 1 sowie die in Fig. 2 dargestellte Vorrichtung zur Erzeugung von Wasserdampf weist eine Brennkammer 2 auf, in welcher gasförmiger Wasserstoff H2(g) und gasförmiger Sauerstoff O2(g) verbrannt werden, wobei als Produktgas Wasserdampf H2O(g) entsteht. Die Brennkammer 2 wird von einem im Wesentlichen zylindrischen Gehäuse 4 gebildet, dessen offene Stirnseiten von Endplatten 6 und 8 verschlossen sind.In the Fig. 1 as well as in Fig. 2 illustrated apparatus for generating water vapor has a combustion chamber 2, in which gaseous hydrogen H 2 (g) and gaseous oxygen O 2 (g) are burned, wherein as product gas steam H 2 O (g) is formed. The combustion chamber 2 is formed by a substantially cylindrical housing 4, whose open end faces are closed by end plates 6 and 8.

An der Endplatte 6 sind ein Sauerstoffeinlass und ein Wasserstoffeinlass ausgebildet (Fig. 3). Der Sauerstoffeinlass wird von einer Düse 10 gebildet, die an der Endplatte 6 zentral angeordnet ist. Den Wasserstoffeinlass in die Brennkammer 2 bilden zwölf Wasserstoffeinlassöffnungen 12, die mit radialem Abstand zu der Düse 10 ringförmig um diese herum ausgebildet sind. An der der Brennkammer 2 zugewandten Seite ist an der Endplatte 6 eine kegelförmige Vertiefung 14 ausgebildet. An dem spitz zulaufenden Ende dieser Vertiefung 14 mündet die Düse 10.At the end plate 6, an oxygen inlet and a hydrogen inlet are formed ( Fig. 3 ). The oxygen inlet is formed by a nozzle 10 which is centrally located on the end plate 6. The hydrogen inlet into the combustion chamber 2 form twelve hydrogen inlet openings 12, which are formed at a radial distance from the nozzle 10 in an annular manner around it. At the combustion chamber 2 side facing a conical recess 14 is formed on the end plate 6. At the tapered end of this recess 14, the nozzle 10 opens.

Über die Düse 10 als Sauerstoffeinlass wird neben dem Sauerstoff O2(g) auch flüssiges Wasser H2O(fl) in die Brennkammer 2 eingeleitet. Hierzu sind an der Düse 10 eingangsseitig ein Anschluss 16 zum Anschluss einer von einer Sauerstoffquelle kommenden Zuführleitung und ein Anschluss 18 zum Anschluss einer von einer Wasserquelle kommenden Zuführleitung ausgebildet. Auf die Darstellung der Sauerstoffquelle, der Wasserquelle und der Zuführleitungen ist aus Gründen der besseren Übersichtlichkeit verzichtet worden.In addition to the oxygen O 2 (g) , liquid water H 2 O (fl) is also introduced into the combustion chamber 2 via the nozzle 10 as the oxygen inlet. For this purpose, a connection 16 for connecting a supply line coming from an oxygen source and a connection 18 for connecting a supply line coming from a water source are formed on the inlet side of the nozzle 10. On the representation of the oxygen source, the water source and the supply lines has been omitted for reasons of clarity.

Das Gehäuse 4 sowie die Endplatte 6 sind an ihrer der Brennkammer 2 zugewandten Innenseite mit Wärmedämmplatten 20 verkleidet. Durch die Endplatte 6 ist ein Zünder 22 einer elektrischen Zündeinrichtung in das Innere der Brennkammer 2 geführt, die dort zum Erzeugen einer Wasserstoff-Sauerstoff-Flamme dient.The housing 4 and the end plate 6 are clad on their inner side facing the combustion chamber 2 with thermal insulation panels 20. Through the end plate 6, an igniter 22 of an electric ignition device is guided into the interior of the combustion chamber 2, which serves there for generating a hydrogen-oxygen flame.

An der Endplatte 8 ist zentral ein Wasserdampfauslass 24 angeordnet. Dieser Wasserdampfauslass 24 wird von einer kritischen Düse gebildet. Mit radialem Abstand um den Wasserdampfauslass 24 herum sind an der Endplatte 8 mehrere Entlastungsbohrungen 26 angeordnet. Der Wasserdampfeinlass 24 mündet in einer Mischkammer 28. Diese Mischkammer 28 wird von einem im Wesentlichen zylindrischen Gehäuse 30 gebildet, welches an der Endplatte 8 an der von der Brennkammer 2 abgewandten Seite angeflanscht ist. An dem Gehäuse 30 ist an einem von der Endplatte 8 abgewandten Ende ein Auslass 32 ausgebildet. In der Mischkammer 28 sind in dem Strömungspfad von dem Wasserstoffauslass 24, der einen Wasserstoffeinlass in die Mischkammer 28 bildet, und dem Auslass 32 hintereinander mehrere Segmente 34 aus einem porösen Material, wie z. B. Drahtgestrick, angeordnet.At the end plate 8, a water vapor outlet 24 is arranged centrally. This steam outlet 24 is formed by a critical nozzle. At a radial distance around the steam outlet 24, a plurality of relief bores 26 are arranged on the end plate 8. The steam inlet 24 opens into a mixing chamber 28. This mixing chamber 28 is formed by a substantially cylindrical housing 30, which is flanged to the end plate 8 on the side facing away from the combustion chamber 2 side. An outlet 32 is formed on the housing 30 at an end remote from the end plate 8. In the mixing chamber 28 are in the flow path of the hydrogen outlet 24, which forms a hydrogen inlet into the mixing chamber 28, and the outlet 32 in succession a plurality of segments 34 made of a porous material, such. B. wire knit arranged.

An der Außenseite des die Brennkammer 2 bildenden Gehäuses 4 ist eine sich schraubenförmig um den Umfang des Gehäuses 4 windende Nut 36 ausgebildet. Die Nut 36 dient zur Aufnahme eines Kühlwasserkanals in Form einer Leitung 38. Anströmseitig ist die Leitung 38 mit einer in der Zeichnung nicht dargestellten Wasserquelle verbunden. Abströmseitig der Leitung 38 besteht eine in der Zeichnung ebenfalls nicht dargestellte Strömungsverbindung zwischen der Leitung 38 und der Düse 10 sowie zwischen der Leitung 38 und dem an der Endplatte 8 ausgebildeten Wasserdampfauslass 24, wobei ein Teil dieser Leitungsverbindung von einer an der Endplatte 8 ausgebildeten Bohrung 40 (Fig. 4) gebildet wird, die von der Außenseite der Endplatte 8 radial nach innen verläuft und in den Wasserdampfauslass 24 mündet.On the outside of the combustion chamber 2 forming the housing 4 is a helically around the circumference of the housing 4 spiraling groove 36 is formed. The groove 36 serves to receive a cooling water channel in the form of a line 38. On the inflow side, the line 38 is connected to a water source, not shown in the drawing. Downstream of the conduit 38 there is also a flow connection, not shown in the drawing, between the conduit 38 and the nozzle 10 and between the conduit 38 and the water vapor outlet 24 formed on the end plate 8, a portion of this conduit connection being formed by a bore 40 formed on the end plate 8 ( Fig. 4 ) is formed, which extends from the outside of the end plate 8 radially inwardly and opens into the steam outlet 24.

Der Verfahrensablauf bei Einsatz der in der Zeichnung dargestellten Vorrichtung ist wie folgt:

  • Zur Erzeugung von Wasserdampf H2O(g) wird der Brennkammer 2 voneinander räumlich getrennt Wasserstoff H2(g) und Sauerstoff O2(g) im stöchiometrischen Verhältnis zugeführt. Die Einleitung des Wasserstoffs H2(g) erfolgt über die Wasserstoffeinlassöffnungen 12, während der Sauerstoff O2(g) über die Düse 10 in die Brennkammer 2 eingeleitet wird. In der Brennkammer 2 wird das Wasserstoff-Sauerstoff-Gemisch mittels des Zünders 22 gezündet, woraufhin es unter Bildung einer Wasser-Sauerstoff-Flamme verbrennt und als Produktgas reiner Wasserdampf H2O(g) erzeugt wird.
The procedure when using the device shown in the drawing is as follows:
  • In order to generate steam H 2 O (g) , the combustion chamber 2 is supplied with hydrogen H 2 (g) and oxygen O 2 (g) in a stoichiometric ratio in a spatially separated manner. The introduction of the hydrogen H 2 (g) takes place via the hydrogen inlet openings 12, while the oxygen O 2 (g) is introduced into the combustion chamber 2 via the nozzle 10. In the combustion chamber 2, the hydrogen-oxygen mixture is ignited by means of the igniter 22, whereupon it burns to form a water-oxygen flame and as product gas pure water vapor H 2 O (g) is generated.

Während der Verbrennung des Wasserstoffs H2(g) mit dem Sauerstoff O2(g) wird die Brennkammer 2 mittels durch die Leitung 38 fließenden Wassers H2O(fl) gekühlt. Ein Teil dieses Wassers H2O(fl) wird dem Sauerstoffstrom in der Düse 10 zugeführt, von wo es zerstäubt mit dem Sauerstoff O2(g) in die Brennkammer 2 gelangt. Dort verdampft das Wasser H2O(fl) zu zusätzlichem Wasserdampf H2O(g). Durch das mit dem Sauerstoff O2(g) in die Brennkammer 2 eingeleitete Wasser H2O(fl) beträgt die Reaktionstemperatur in der Brennkammer 2 lediglich 950 bis 1.050°C.During the combustion of the hydrogen H 2 (g) with the oxygen O 2 (g) , the combustion chamber 2 is cooled by means of water flowing through the line 38 H 2 O (fl) . Part of this water H 2 O (fl) is supplied to the oxygen stream in the nozzle 10, from where it enters the combustion chamber 2 atomized with the oxygen O 2 (g) . There, the water evaporates H 2 O (fl) to additional water vapor H 2 O (g) . By the oxygen O 2 (g) introduced into the combustion chamber 2 water H 2 O (fl), the reaction temperature in the combustion chamber 2 only 950 to 1050 ° C.

Über den Wasserdampfauslass 24 gelangt der Wasserdampf H2O(g) von der Brennkammer 2 in die Mischkammer 28, wobei dem Wasserdampfstrom in dem Wasserdampfauslass 24 ein weiterer Teil des zur Kühlung der Brennkammer 2 durch die Leitung 28 fließenden Wassers H2O(fl) hinzugefügt wird und so in die Mischkammer 28 gelangt. Zuvor wird dieses Wasser H2O(fl) von dem durch den Wasserauslass 24 fließenden Wasserdampfstrom zerstäubt. Aufgrund der Temperatur des Wasserdampfs H2O(g) verdampft auch das flüssige Wasser H2O(fl) zu Wasserdampf H2O(g), wobei dem Wasserdampf H2O(g) aber aufgrund der Vermengung mit dem flüssigen Wasser H2O(fl) Wärme entzogen wird. Auf diese Weise lässt sich die Temperatur des Wasserdampfs H2O(g) in Abhängigkeit von der dem Wasserdampf H2O(g) zugeführten Menge an flüssigem Wasser H2O(fl) in der Mischkammer 28 in einem weiten Bereich steuern.About the Wasserdampfauslass 24 of the water vapor passes H 2 O (g) of the combustion chamber 2 into the mixing chamber 28, wherein the water vapor stream in the Wasserdampfauslass 24 is a further part of the current flowing to the cooling of the combustion chamber 2 through line 28 water H 2 O (fl) is added and thus enters the mixing chamber 28. Previously, this water is sputtered from the water vapor stream flowing through the water outlet 24 H 2 O (fl) . Due to the temperature of the water vapor H 2 O (g) and the liquid water H 2 O (fl ) evaporated to steam H 2 O (g) , the water vapor H 2 O (g) but due to the mixing with the liquid water H 2 O (fl) heat is removed. In this way, the temperature of the water vapor H 2 O (g) in dependence on the water vapor H 2 O (g) supplied amount of liquid water H 2 O (fl) in the mixing chamber 28 in a wide range.

Der erzeugte Wasserdampf H2O(g) verlässt die Mischkammer 28 durch den Auslass 32, wo er für verschiedenste Anwendungen zur Verfügung steht. Zuvor wird er in der Mischkammer 28 hinsichtlich seiner Temperatur homogenisiert, indem er die in der Mischkammer 28 befindlichen porösen Segmente 34 durchströmt.The generated water vapor H 2 O (g) leaves the mixing chamber 28 through the outlet 32, where it is available for a variety of applications. Previously, it is homogenized in the mixing chamber 28 with respect to its temperature by flowing through the porous segments 34 located in the mixing chamber 28.

BezugszeichenlisteLIST OF REFERENCE NUMBERS

22
- Brennkammer- combustion chamber
44
- Gehäuse- Casing
66
- Endplatte- End plate
88th
- Endplatte- End plate
1010
- Düse- Jet
1212
- Wasserstoffeinlassöffnung- Hydrogen inlet opening
1414
- Vertiefung- Deepening
1616
- Anschluss- Connection
1818
- Anschluss- Connection
2020
- Wärmedämmplatte- thermal insulation board
2222
- Zünder- detonator
2424
- Wasserdampfauslass- Steam outlet
2626
- Entlastungsbohrung- Relief bore
2828
- Mischkammer- mixing chamber
3030
- Gehäuse- Casing
3232
- Auslass- outlet
3434
- Segment- Segment
3636
- Nut- groove
3838
- Leitung- Management
4040
- Bohrung- Drilling
H2(g) H 2 (g)
- Wasserstoff- hydrogen
H2O(fl) H 2 O (fl)
- Wasser- Water
H2O(g) H 2 O (g)
- Wasserdampf- Steam
O2(g) O 2 (g)
- Sauerstoff- oxygen

Claims (13)

  1. Method for generating water vapor (H2O(g)), in which hydrogen (H2(g)) and oxygen (O2(g)) are combusted in a combustion chamber (2) while adding water (H2O(fl)), characterized in that the water (H2O(fl)) in a liquid state is directed into the combustion chamber (2) in a common volume flow with the oxygen (O2(g)).
  2. Method according to Claim 1, characterized in that additional liquid water (H2O(fl)) is added on the outlet side of the combustion chamber (2) to the water vapor (H2O(g)) which is generated in the combustion chamber (2).
  3. Method according to one of the preceding claims, characterized in that liquid water (H2O(fl)) which is to be evaporated is used in advance for cooling the outer wall of the combustion chamber (2).
  4. Method according to one of the preceding claims, characterized in that the water (H2O(fl)) which is fed to the combustion chamber (2) is atomized by means of the oxygen stream before introduction into the combustion chamber (2).
  5. Method according to Claims 2 and 4, characterized in that the water (H2O(fl)) which is added on the outlet side of the combustion chamber (2) to the water vapor (H2O(g)) which is generated in the combustion chamber (2) is atomized by means of the water vapor stream.
  6. Apparatus for generating water vapor (H2O(g)), featuring a combustion chamber (2) which has a hydrogen inlet and an oxygen inlet (10), characterized in that the oxygen inlet (10) is connected on the inlet side to a water source via a feed pipe which can be shut off.
  7. Apparatus according to Claim 6, characterized in that on the outlet side of the combustion chamber (2) a water vapor outlet (24) opens into a mixing chamber (28) which has a water inlet.
  8. Apparatus according to one of Claims 6 or 7, characterized in that the hydrogen inlet is arranged on the combustion chamber (2) concentrically around the oxygen inlet (10).
  9. Apparatus according to Claim 7 or according to Claims 7 and 8, characterized in that the water vapor outlet (24) of the combustion chamber (2) forms the water inlet of the mixing chamber (28).
  10. Apparatus according to Claim 7 or according to Claims 7 and 8 or according to Claims 7, 8 and 9, characterized in that the water vapor outlet (24) is designed as a critical nozzle.
  11. Apparatus according to one of Claims 7 to 10, characterized in that the mixing chamber (28) is filled with a porous material.
  12. Apparatus according to one of Claims 6 to 11, characterized in that at least one cooling water passage, which is fluidically connected to a water source, is formed on an outer wall of the combustion chamber (2), and on the outflow side is fluidically connected to the oxygen inlet (10) in the combustion chamber (2) and/or to the water vapor outlet (24) of the combustion chamber (2).
  13. Submarine, characterized in that it has an apparatus for generating water vapor (H2O(g)) having the features which are disclosed in Claims 6 to 12.
EP13824103.9A 2012-10-29 2013-10-28 Method for producing steam Active EP2912374B1 (en)

Applications Claiming Priority (2)

Application Number Priority Date Filing Date Title
DE201210219755 DE102012219755A1 (en) 2012-10-29 2012-10-29 Method for generating water vapor
PCT/DE2013/200253 WO2014067519A1 (en) 2012-10-29 2013-10-28 Method for generating water vapour

Publications (2)

Publication Number Publication Date
EP2912374A1 EP2912374A1 (en) 2015-09-02
EP2912374B1 true EP2912374B1 (en) 2016-11-30

Family

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Family Applications (1)

Application Number Title Priority Date Filing Date
EP13824103.9A Active EP2912374B1 (en) 2012-10-29 2013-10-28 Method for producing steam

Country Status (6)

Country Link
EP (1) EP2912374B1 (en)
KR (1) KR101962513B1 (en)
AU (1) AU2013339866B2 (en)
DE (1) DE102012219755A1 (en)
ES (1) ES2616479T3 (en)
WO (1) WO2014067519A1 (en)

Families Citing this family (2)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
EP3202710A1 (en) 2016-02-08 2017-08-09 Linde Aktiengesellschaft Method for chemically converting one or more hydrocarbon reactants
GB2589602B (en) 2019-12-04 2022-04-27 Steamology Motion Ltd Steam generator

Family Cites Families (17)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
DE168037C (en) *
US2299849A (en) * 1940-07-19 1942-10-27 Thomas J Rees Steam generating plant
DE977651C (en) * 1954-12-31 1967-12-28 Siemens Ag Process for generating superheated water vapor
US3983882A (en) * 1973-08-03 1976-10-05 Billings Energy Research Corporation Method and apparatus for hydrogen fueled internal combustion engines
US4167919A (en) * 1977-11-28 1979-09-18 Billings Energy Corporation Method and apparatus for hydrogen fueled internal combustion engines
DE2830896A1 (en) * 1978-07-13 1980-01-24 Ingo Gierstorfer IC engine using fuel-oxygen-water vapour mixt. - has evaporator extracting heat from cooling water and condenser system
US4332219A (en) * 1980-11-18 1982-06-01 Ernesto Gonzalez Electrocombustion engine
DE3512947A1 (en) * 1985-04-11 1986-10-16 Deutsche Forschungs- und Versuchsanstalt für Luft- und Raumfahrt e.V., 5300 Bonn METHOD FOR PRODUCING WATER VAPOR AND STEAM GENERATOR FOR CARRYING OUT THIS METHOD
JPS62104038A (en) * 1985-07-15 1987-05-14 Dainippon Screen Mfg Co Ltd Steam-containing oxygen gas supplying device
AT391740B (en) * 1985-11-20 1990-11-26 Fuerlinger Rupert Internal combustion engine operated with hydrogen
US5234501A (en) * 1987-09-01 1993-08-10 Tokyo Electron Sagami Limited Oxidation metod
US6289666B1 (en) * 1992-10-27 2001-09-18 Ginter Vast Corporation High efficiency low pollution hybrid Brayton cycle combustor
DE10211738B4 (en) * 2002-03-14 2006-06-08 Infineon Technologies Ag Method and device for producing an ultrapure mixture of water vapor and oxygen
KR20040015644A (en) * 2002-08-13 2004-02-19 주식회사 제이에이치에너지 Sprayer and mixer of oxygen, hydrogen and liquid fuel for burner
DE10243250A1 (en) * 2002-09-17 2004-03-25 Alstom (Switzerland) Ltd. Production of steam as working medium involves passing fuel and oxidizer into reaction zone, passing hot reaction gases into vaporizing zone, introducing water into vaporizing zone, and further processing
US7128624B1 (en) * 2005-04-28 2006-10-31 Lockheed Martin Corporation Rechargeable open cycle underwater propulsion system
US8522871B2 (en) * 2009-03-04 2013-09-03 Clean Energy Systems, Inc. Method of direct steam generation using an oxyfuel combustor

Also Published As

Publication number Publication date
KR101962513B1 (en) 2019-03-26
ES2616479T3 (en) 2017-06-13
KR20150076243A (en) 2015-07-06
EP2912374A1 (en) 2015-09-02
AU2013339866A1 (en) 2015-05-28
DE102012219755A1 (en) 2014-04-30
WO2014067519A1 (en) 2014-05-08
AU2013339866B2 (en) 2017-05-11

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